CY7C64713 EZ-USB FX1™ USB Microcontroller Full-speed USB Peripheral Controller Features ■ ■ ■ ❐ Up to 48 MHz clock rate ❐ Four clocks for each instruction cycle Fit, form, and function upgradable to the FX2LP (CY7C68013A) ❐ Two USARTS ❐ Pin compatible ❐ Three counters or timers ❐ Object code compatible ❐ Expanded interrupt system ❐ Functionally compatible (FX1 functionality is a Subset of the FX2LP) ❐ Two data pointers Single chip integrated USB transceiver, SIE, and enhanced 8051 microprocessor ■ Draws no more than 65 mA in any mode, making the FX1 suitable for bus powered applications ■ Software: 8051 runs from internal RAM, which is: ❐ Downloaded using USB ❐ Loaded from EEPROM ❐ External memory device (128 pin configuration only) ■ 16 KBytes of on-chip Code/Data RAM ■ Four programmable BULK/INTERRUPT/ISOCHRONOUS endpoints ❐ ■ Integrated, industry standard 8051 with enhanced features: ■ 3.3V operation with 5V tolerant inputs ■ Smart SIE ■ Vectored USB interrupts ■ Separate data buffers for the Setup and DATA portions of a CONTROL transfer ■ Integrated I2C controller, running at 100 or 400 KHz ■ 48 MHz, 24 MHz, or 12 MHz 8051 operation ■ Four integrated FIFOs Buffering options: double, triple, and quad Additional programmable (BULK/INTERRUPT) 64-byte endpoint ■ 8 or 16-bit external data interface ■ Smart Media Standard ECC generation ■ GPIF ❐ Allows direct connection to most parallel interfaces; 8 and 16-bit ❐ Brings glue and FIFOs inside for lower system cost ❐ Automatic conversion to and from 16-bit buses ❐ Master or slave operation ❐ FIFOs can use externally supplied clock or asynchronous strobes ❐ Easy interface to ASIC and DSP ICs ■ Vectored for FIFO and GPIF interrupts ■ Up to 40 General Purpose IOs (GPIO) ■ Four package options: ❐ Programmable waveform descriptors and configuration registers to define waveforms ❐ 128 pin TQFP ❐ Supports multiple Ready (RDY) inputs and Control (CTL) outputs ❐ 100 pin TQFP ❐ 56 pin SSOP ❐ 56 pin QFN Pb-free Cypress Semiconductor Corporation Document #: 38-08039 Rev. *E • 198 Champion Court • San Jose, CA 95134-1709 • 408-943-2600 Revised February 06, 2008 [+] Feedback CY7C64713 Logic Block Diagram High performance micro using standard tools with lower-power options x20 PLL VCC /0.5 /1.0 /2.0 Data (8) Address (16) FX1 8051 Core 12/24/48 MHz, four clocks/cycle 1.5k connected for enumeration D+ USB D– XCVR CY Smart 16 KB RAM Address (16) / Data Bus (8) 24 MHz Ext. XTAL I2C Master Abundant IO including two USARTS Additional IOs (24) ADDR (9) GPIF RDY (6) CTL (6) ECC USB Engine Integrated full speed XCVR 4 kB FIFO Enhanced USB core Simplifies 8051 code Document #: 38-08039 Rev. *E ‘Soft Configuration’ Easy firmware changes 8/16 General programmable I/F to ASIC/DSP or bus standards such as ATAPI, EPP, etc. Up to 96 MBytes burst rate FIFO and endpoint memory (master or slave operation) Page 2 of 54 [+] Feedback CY7C64713 Functional Description 8051 Microprocessor EZ-USB FX1™ (CY7C64713) is a full speed, highly integrated, USB microcontroller. By integrating the USB transceiver, Serial Interface Engine (SIE), enhanced 8051 microcontroller, and a programmable peripheral interface in a single chip, Cypress has created a very cost effective solution that provides superior time-to-market advantages. The 8051 microprocessor embedded in the FX1 family has 256 bytes of register RAM, an expanded interrupt system, three timer/counters, and two USARTs. The EZ-USB FX1 is more economical, because it incorporates the USB transceiver and provides a smaller footprint solution than the USB SIE or external transceiver implementations. With EZ-USB FX1, the Cypress Smart SIE handles most of the USB protocol in hardware, freeing the embedded microcontroller for application specific functions and decreasing the development time to ensure USB compatibility. The General Programmable Interface (GPIF) and Master/Slave Endpoint FIFO (8 or 16-bit data bus) provide an easy and glueless interface to popular interfaces such as ATA, UTOPIA, EPP, PCMCIA, and most DSP/processors. Four Pb-free packages are defined for the family: 56 SSOP, 56 QFN, 100 TQFP, and 128 TQFP. 8051 Clock Frequency FX1 has an on-chip oscillator circuit that uses an external 24 MHz (±100 ppm) crystal with the following characteristics: ■ Parallel resonant ■ Fundamental mode ■ 500 μW drive level ■ 12 pF (5% tolerance) load capacitors. An on-chip PLL multiplies the 24 MHz oscillator up to 480 MHz, as required by the transceiver/PHY, and the internal counters divide it down for use as the 8051 clock. The default 8051 clock frequency is 12 MHz. The clock frequency of the 8051 is dynamically changed by the 8051 through the CPUCS register. Applications The CLKOUT pin, which is three-stated and inverted using the internal control bits, outputs the 50% duty cycle 8051 clock at the selected 8051 clock frequency which is 48, 24, or 12 MHz. ■ DSL modems USARTS ■ ATA interface ■ Memory card readers ■ Legacy conversion devices FX1 contains two standard 8051 USARTs, addressed by Special Function Register (SFR) bits. The USART interface pins are available on separate IO pins, and are not multiplexed with port pins. ■ Home PNA ■ Wireless LAN ■ MP3 players ■ Networking The Reference Designs section of the cypress website provides additional tools for typical USB applications. Each reference design comes complete with firmware source and object code, schematics, and documentation. Please visit http://www.cypress.com for more information. Functional Overview USB Signaling Speed FX1 operates at one of the three rates defined in the USB Specification Revision 2.0, dated April 27, 2000: Full speed, with a signaling bit rate of 12 Mbps. UART0 and UART1 can operate using an internal clock at 230 KBaud with no more than 1% baud rate error. 230 KBaud operation is achieved by an internally derived clock source that generates overflow pulses at the appropriate time. The internal clock adjusts for the 8051 clock rate (48, 24, 12 MHz) such that it always presents the correct frequency for 230-KBaud operation.[1] Special Function Registers Certain 8051 SFR addresses are populated to provide fast access to critical FX1 functions. These SFR additions are shown in Table 1 on page 4. Bold type indicates non-standard, enhanced 8051 registers. The two SFR rows that end with ‘0’ and ‘8’ contain bit addressable registers. The four IO ports A–D use the SFR addresses used in the standard 8051 for ports 0–3, which are not implemented in the FX1. Because of the faster and more efficient SFR addressing, the FX1 IO ports are not addressable in the external RAM space (using the MOVX instruction). FX1 does not support the low speed signaling mode of 1.5 Mbps or the high speed mode of 480 Mbps. Figure 1. Crystal Configuration C1 24 MHz 12 pF C2 12 pF 12-pF capacitor values assumes a trace capacitance of 3 pF per side on a four layer FR4 PCA 20 × PLL Note 1. 115-KBaud operation is also possible by programming the 8051 SMOD0 or SMOD1 bits to a ‘1’ for UART0 and UART1, respectively. Document #: 38-08039 Rev. *E Page 3 of 54 [+] Feedback CY7C64713 Table 1. Special Function Registers x 8x 9x Ax Bx Cx Dx Ex Fx 0 IOA IOB IOC IOD SCON1 PSW ACC B SBUF1 EICON EIE EIP 1 SP EXIF INT2CLR IOE 2 DPL0 MPAGE INT4CLR OEA 3 DPH0 OEB 4 DPL1 OEC 5 DPH1 OED 6 DPS OEE 7 PCON 8 TCON 9 TMOD SBUF0 A TL0 AUTOPTRH1 B TL1 C TH0 D TH1 AUTOPTRH2 GPIFSGLDATH E CKCON AUTOPTRL2 GPIFSGLDATLX F SCON0 IE IP T2CON EP2468STAT EP01STAT RCAP2L AUTOPTRL1 EP24FIFOFLGS GPIFTRIG RCAP2H reserved EP68FIFOFLGS reserved AUTOPTRSETUP TL2 TH2 GPIFSGLDATLNOX I2C Bus ReNumeration™ FX1 supports the I2C bus as a master only at 100/400 KHz. SCL and SDA pins have open drain outputs and hysteresis inputs. These signals must be pulled up to 3.3V, even if no I2C device is connected. Because the FX1’s configuration is soft, one chip can take on the identities of multiple distinct USB devices. Buses All packages: 8 or 16-bit ‘FIFO’ bidirectional data bus, multiplexed on IO ports B and D. 128 pin package: adds 16-bit output only 8051 address bus, 8-bit bidirectional data bus. USB Boot Methods 2 During the power up sequence, internal logic checks the I C port for the connection of an EEPROM whose first byte is either 0xC0 or 0xC2. If found, it uses the VID/PID/DID values in the EEPROM in place of the internally stored values (0xC0). Alternatively, it boot-loads the EEPROM contents into an internal RAM (0xC2). If no EEPROM is detected, FX1 enumerates using internally stored descriptors. The default ID values for FX1 are VID/PID/DID (0x04B4, 0x6473, 0xAxxx where xxx=Chip revision).[2] Table 2. Default ID Values for FX1 Default VID/PID/DID Vendor ID 0x04B4 Cypress Semiconductor Product ID 0x6473 EZ-USB FX1 Device release 0xAnnn Depends on chip revision (nnn = chip revision where first silicon = 001) When first plugged into the USB, the FX1 enumerates automatically and downloads firmware and the USB descriptor tables over the USB cable. Next, the FX1 enumerates again, this time as a device defined by the downloaded information. This patented two step process, called ReNumeration, happens instantly when the device is plugged in, with no indication that the initial download step has occurred. Two control bits in the USBCS (USB Control and Status) register control the ReNumeration process: DISCON and RENUM. To simulate a USB disconnect, the firmware sets DISCON to 1. To reconnect, the firmware clears DISCON to 0. Before reconnecting, the firmware sets or clears the RENUM bit to indicate if the firmware or the Default USB Device handles device requests over endpoint zero: ■ RENUM = 0, the Default USB Device handles device requests ■ RENUM = 1, the firmware handles device requests Bus-powered Applications The FX1 fully supports bus powered designs by enumerating with less than 100 mA as required by the USB specification. Interrupt System INT2 Interrupt Request and Enable Registers FX1 implements an autovector feature for INT2 and INT4. There are 27 INT2 (USB) vectors, and 14 INT4 (FIFO/GPIF) vectors. See EZ-USB Technical Reference Manual (TRM) for more details. Note 2. The I2C bus SCL and SDA pins must be pulled up, even if an EEPROM is not connected. Otherwise this detection method does not work properly. Document #: 38-08039 Rev. *E Page 4 of 54 [+] Feedback CY7C64713 USB-Interrupt Autovectors The main USB interrupt is shared by 27 interrupt sources. The FX1 provides a second level of interrupt vectoring, called Autovectoring, to save code and processing time that is normally required to identify the individual USB interrupt source. When a USB interrupt is asserted, the FX1 pushes the program counter on to its stack and then jumps to address 0x0043, where it expects to find a “jump” instruction to the USB Interrupt service routine. The FX1 jump instruction is encoded as shown in Table 3. If Autovectoring is enabled (AV2EN = 1 in the INTSETUP register), the FX1 substitutes its INT2VEC byte. Therefore, if the high byte (“page”) of a jump table address is preloaded at location 0x0044, the automatically inserted INT2VEC byte at 0x0045 directs the jump to the correct address out of the 27 addresses within the page. FIFO/GPIF Interrupt (INT4) Just as the USB Interrupt is shared among 27 individual USB-interrupt sources, the FIFO/GPIF interrupt is shared among 14 individual FIFO/GPIF sources. The FIFO/GPIF Interrupt, such as the USB Interrupt, can employ autovectoring. Table 4 on page 6 shows the priority and INT4VEC values for the 14 FIFO/GPIF interrupt sources. Table 3. INT2 USB Interrupts USB INTERRUPT TABLE FOR INT2 Priority INT2VEC Value 1 00 SUDAV Setup Data Available 2 04 SOF Start of Frame 3 08 SUTOK Setup Token Received 4 0C SUSPEND USB Suspend request 5 10 USB RESET Bus reset 6 14 7 18 8 1C Source Notes Reserved EP0ACK FX1 ACK’d the CONTROL Handshake Reserved 9 20 EP0-IN EP0-IN ready to be loaded with data 10 24 EP0-OUT EP0-OUT has USB data 11 28 EP1-IN EP1-IN ready to be loaded with data 12 2C EP1-OUT EP1-OUT has USB data 13 30 EP2 IN: buffer available. OUT: buffer has data 14 34 EP4 IN: buffer available. OUT: buffer has data 15 38 EP6 IN: buffer available. OUT: buffer has data 16 3C EP8 IN: buffer available. OUT: buffer has data 17 40 IBN IN-Bulk-NAK (any IN endpoint) 18 44 Reserved 19 48 EP0PING EP0 OUT was Pinged and it NAK’d 20 4C EP1PING EP1 OUT was Pinged and it NAK’d 21 50 EP2PING EP2 OUT was Pinged and it NAK’d 22 54 EP4PING EP4 OUT was Pinged and it NAK’d 23 58 EP6PING EP6 OUT was Pinged and it NAK’d 24 5C EP8PING EP8 OUT was Pinged and it NAK’d 25 60 ERRLIMIT Bus errors exceeded the programmed limit 26 64 27 68 Reserved 28 6C Reserved 29 70 EP2ISOERR ISO EP2 OUT PID sequence error 30 74 EP4ISOERR ISO EP4 OUT PID sequence error 31 78 EP6ISOERR ISO EP6 OUT PID sequence error 32 7C EP8ISOERR ISO EP8 OUT PID sequence error Document #: 38-08039 Rev. *E Page 5 of 54 [+] Feedback CY7C64713 Table 4. Individual FIFO/GPIF Interrupt Sources Priority INT4VEC Value 1 80 Source Notes EP2PF Endpoint 2 Programmable Flag 2 84 EP4PF Endpoint 4 Programmable Flag 3 88 EP6PF Endpoint 6 Programmable Flag 4 8C EP8PF Endpoint 8 Programmable Flag 5 90 EP2EF Endpoint 2 Empty Flag 6 94 EP4EF Endpoint 4 Empty Flag 7 98 EP6EF Endpoint 6 Empty Flag 8 9C EP8EF Endpoint 8 Empty Flag 9 A0 EP2FF Endpoint 2 Full Flag 10 A4 EP4FF Endpoint 4 Full Flag 11 A8 EP6FF Endpoint 6 Full Flag 12 AC EP8FF Endpoint 8 Full Flag 13 B0 GPIFDONE GPIF Operation Complete 14 B4 GPIFWF GPIF Waveform If Autovectoring is enabled (AV4EN = 1 in the INTSETUP register), the FX1 substitutes its INT4VEC byte. Therefore, if the high byte (“page”) of a jump-table address is preloaded at location 0x0054, the automatically inserted INT4VEC byte at 0x0055 directs the jump to the correct address out of the 14 addresses within the page. When the ISR occurs, the FX1 pushes the program counter onto its stack and then jumps to address 0x0053, where it expects to find a “jump” instruction to the ISR Interrupt service routine. of the crystal and the PLL. This reset period must be approximately 5 ms after VCC has reached 3.0 Volts. If the crystal input pin is driven by a clock signal the internal PLL stabilizes in 200 μs after VCC has reached 3.0V[3]. Figure 2 shows a power on reset condition and a reset applied during operation. A power on reset is defined as the time a reset is asserted when power is being applied to the circuit. A powered reset is defined to be when the FX1 has been previously powered on and operating and the RESET# pin is asserted. Reset and Wakeup Cypress provides an application note which describes and recommends power on reset implementation and is found on the Cypress web site. While the application note discusses the FX2, the information provided applies also to the FX1. For more information on reset implementation for the FX2 family of products visit http://www.cypress.com. Reset Pin The input pin, RESET#, resets the FX1 when asserted. This pin has hysteresis and is active LOW. When a crystal is used with the CY7C64713, the reset period must allow for the stabilization Figure 2. Reset Timing Plots RESET# RESET# VIL VIL 3.3V 3.0V 3.3V VCC VCC 0V 0V TRESET Power on Reset TRESET Powered Reset Note 3. If the external clock is powered at the same time as the CY7C64713 and has a stabilization wait period. It must be added to the 200 μs. Document #: 38-08039 Rev. *E Page 6 of 54 [+] Feedback CY7C64713 Program/Data RAM Table 5. Reset Timing Values Condition TRESET Power On Reset with crystal 5 ms Power On Reset with external clock 200 μs + Clock stability time Powered Reset 200 μs Size The FX1 has 16 KBytes of internal program/data RAM, where PSEN#/RD# signals are internally ORed to allow the 8051 to access it as both program and data memory. No USB control registers appear in this space. Two memory maps are shown in the following diagrams: Wakeup Pins ■ Figure 3 Internal Code Memory, EA = 0 The 8051 puts itself and the rest of the chip into a power down mode by setting PCON.0 = 1. This stops the oscillator and PLL. When WAKEUP is asserted by external logic, the oscillator restarts, after the PLL stabilizes, and then the 8051 receives a wakeup interrupt. This applies irrespective of whether the FX1 is connected to the USB or not. ■ Figure 4 External Code Memory, EA = 1. The FX1 exits the power down (USB suspend) state using one of the following methods: Internal Code Memory, EA = 0 This mode implements the internal 16 KByte block of RAM (starting at 0) as combined code and data memory. When the external RAM or ROM is added, the external read and write strobes are suppressed for memory spaces that exist inside the chip. This allows the user to connect a 64 KByte memory without requiring the address decodes to keep clear of internal memory spaces. ■ USB bus activity (if D+/D– lines are left floating, noise on these lines may indicate activity to the FX1 and initiate a wakeup). ■ External logic asserts the WAKEUP pin. Only the internal 16 KBytes and scratch pad 0.5 KBytes RAM spaces have the following access: ■ External logic asserts the PA3/WU2 pin. ■ USB download ■ USB upload ■ Setup data pointer ■ I2C interface boot load The second wakeup pin, WU2, can also be configured as a general purpose IO pin. This allows a simple external R-C network to be used as a periodic wakeup source. Note that WAKEUP is by default active LOW. Figure 3. Internal Code Memory, EA = 0. Inside FX1 Outside FX1 FFFF 7.5 KBytes USB regs and 4K FIFO buffers (RD#,WR#) E200 E1FF 0.5 KBytes RAM E000 Data (RD#,WR#)* (OK to populate data memory here—RD#/WR# strobes are not active) 40 KBytes External Data Memory (RD#,WR#) 48 KBytes External Code Memory (PSEN#) 3FFF 16 KBytes RAM Code and Data (PSEN#,RD#,WR#)* (Ok to populate data memory here—RD#/WR# strobes are not active) (OK to populate program memory here— PSEN# strobe is not active) 0000 Data Code 2 *SUDPTR, USB upload/download, I C interface boot access Document #: 38-08039 Rev. *E Page 7 of 54 [+] Feedback CY7C64713 External Code Memory, EA = 1 The bottom 16 KBytes of program memory is external, and therefore the bottom 16 KBytes of internal RAM is accessible only as data memory. Figure 4. External Code Memory, EA = 1 Inside FX1 Outside FX1 FFFF 7.5 KBytes USB regs and 4K FIFO buffers (RD#,WR#) E200 E1FF 0.5 KBytes RAM E000 Data (RD#,WR#)* (OK to populate data memory here—RD#/WR# strobes are not active) 40 KBytes External Data Memory (RD#,WR#) 64 KBytes External Code Memory (PSEN#) 3FFF 16 KBytes RAM Data (RD#,WR#)* (Ok to populate data memory here—RD#/WR# strobes are not active) 0000 Data Code *SUDPTR, USB upload/download, I2C interface boot access Figure 5. Register Addresses FFFF 4 KBytes EP2-EP8 buffers (8 x 512) Not all Space is available for all transfer types F000 EFFF 2 KBytes RESERVED E800 E7FF E7C0 E7BF E780 E77F E740 E73F E700 E6FF E500 E4FF E480 E47F E400 E3FF E200 E1FF 64 Bytes EP1IN 64 Bytes EP1OUT 64 Bytes EP0 IN/OUT 64 Bytes RESERVED 8051 Addressable Registers (512) Reserved (128) 128 bytes GPIF Waveforms Reserved (512) 512 bytes 8051 xdata RAM E000 Document #: 38-08039 Rev. *E Page 8 of 54 [+] Feedback CY7C64713 Endpoint RAM Table 6. Default Alternate Settings Size ■ 3 × 64 bytes (Endpoints 0 and 1) Alternate Setting ■ 8 × 512 bytes (Endpoints 2, 4, 6, 8) ep0 64 64 64 64 ep1out 0 64 bulk 64 int 64 int ep1in 0 64 bulk 64 int 64 int ep2 0 64 bulk out (2×) 64 int out (2×) 64 iso out (2×) Organization 0 1 2 3 ■ EP0—Bidirectional endpoint zero, 64 byte buffer ■ EP1IN, EP1OUT—64 byte buffers, bulk or interrupt ep4 0 64 bulk out (2×) 64 bulk out (2×) 64 bulk out (2×) ■ EP2, 4, 6, 8—Eight 512-byte buffers, bulk, interrupt, or isochronous, of which only the transfer size is available. EP4 and EP8 are double buffered, while EP2 and 6 are either double, triple, or quad buffered. Regardless of the physical size of the buffer, each endpoint buffer accommodates only one full speed packet. For bulk endpoints, the maximum number of bytes it can accommodate is 64, even though the physical buffer size is 512 or 1024. For an ISOCHRONOUS endpoint the maximum number of bytes it can accommodate is 1023. For endpoint configuration options, see Figure 6. ep6 0 64 bulk in (2×) 64 int in (2×) ep8 0 64 bulk in (2×) 64 bulk in (2×) 64 bulk in (2×) 64 iso in (2×) External FIFO Interface Architecture The FX1 slave FIFO architecture has eight 512-byte blocks in the endpoint RAM that directly serve as FIFO memories, and are controlled by FIFO control signals (such as IFCLK, SLCS#, SLRD, SLWR, SLOE, PKTEND, and flags). The usable size of these buffers depend on the USB transfer mode as described in the section Organization on page 9. Setup Data Buffer A separate 8-byte buffer at 0xE6B8-0xE6BF holds the Setup data from a CONTROL transfer. In operation, some of the eight RAM blocks fill or empty from the SIE, while the others are connected to the IO transfer logic. The transfer logic takes two forms: the GPIF for internally generated control signals or the slave FIFO interface for externally controlled transfers. Default Alternate Settings In the following table, ‘0’ means “not implemented”, and ‘2×’ means “double buffered”. Figure 6. Endpoint Configuration EP0 IN&OUT 64 64 64 64 64 64 64 64 64 64 64 64 64 64 64 64 64 64 64 64 64 EP1 IN 64 64 64 64 64 EP1 OUT 64 64 64 64 64 64 64 64 64 64 EP2 EP2 EP2 EP2 EP2 EP2 EP2 EP2 EP2 EP2 64 64 64 64 64 64 64 64 64 64 64 64 EP4 EP4 EP4 64 64 64 64 64 64 64 64 64 64 64 EP6 64 64 64 64 EP6 1023 EP8 64 64 64 1 2 Document #: 38-08039 Rev. *E EP6 EP6 64 64 64 64 EP6 1023 1023 3 1023 1023 64 1023 1023 1023 1023 1023 64 64 64 64 4 5 1023 6 EP6 1023 1023 64 EP6 EP6 64 64 64 64 EP6 64 1023 64 EP8 EP8 EP8 64 1023 64 64 EP6 EP2 EP2 64 64 64 64 64 7 8 1023 9 1023 1023 EP8 64 64 64 64 10 1023 11 1023 12 Page 9 of 54 [+] Feedback CY7C64713 Master/Slave Control Signals The FX1 endpoint FIFOS are implemented as eight physically distinct 256x16 RAM blocks. The 8051/SIE can switch any of the RAM blocks between two domains: the USB (SIE) domain and the 8051-IO Unit domain. This switching is done instantaneously, giving essentially zero transfer time between “USB FIFOS” and “Slave FIFOS.” While they are physically the same memory, no bytes are actually transferred between buffers. At any time, some RAM blocks fil or empty with USB data under SIE control, while other RAM blocks are available to the 8051 and the IO control unit. The RAM blocks operate as a single-port in the USB domain, and dual port in the 8051-IO domain. The blocks are configured as single, double, triple, or quad buffered. The IO control unit implements either an internal master (M for master) or external master (S for Slave) interface. In Master (M) mode, the GPIF internally controls FIFOADR[1..0] to select a FIFO. The RDY pins (two in the 56 pin package, six in the 100 pin and 128 pin packages) are used as flag inputs from an external FIFO or other logic if desired. The GPIF is run from either an internally derived clock or an externally supplied clock (IFCLK), at a rate that transfers data up to 96 Megabytes/s (48 MHz IFCLK with 16-bit interface). In Slave (S) mode, the FX1 accepts either an internally derived clock or an externally supplied clock (IFCLK with a maximum frequency of 48 MHz) and SLCS#, SLRD, SLWR, SLOE, PKTEND signals from external logic. When using an external IFCLK, the external clock must be present before switching to the external clock with the IFCLKSRC bit. Each endpoint can individually be selected for byte or word operation by an internal configuration bit, and a Slave FIFO Output Enable signal SLOE enables data of the selected width. External logic must ensure that the output enable signal is inactive when writing data to a slave FIFO. The slave interface can also operate asynchronously, where the SLRD and SLWR signals act directly as strobes, rather than a clock qualifier as in the synchronous mode. The signals SLRD, SLWR, SLOE, and PKTEND are gated by the signal SLCS#. GPIF and FIFO Clock Rates what state a Ready input (or multiple inputs) must be before proceeding. The GPIF vector is programmed to advance a FIFO to the next data value, advance an address, and so on. A sequence of the GPIF vectors create a single waveform that executes to perform the data move between the FX1 and the external device. Six Control OUT Signals The 100 and 128 pin packages bring out all six Control Output pins (CTL0-CTL5). The 8051 programs the GPIF unit to define the CTL waveforms. The 56 pin package brings out three of these signals: CTL0 - CTL2. CTLx waveform edges are programmed to make transitions as fast as once per clock (20.8 ns using a 48 MHz clock). Six Ready IN Signals The 100 and 128 pin packages bring out all six Ready inputs (RDY0–RDY5). The 8051 programs the GPIF unit to test the RDY pins for GPIF branching. The 56 pin package brings out two of these signals, RDY0–1. Nine GPIF Address OUT Signals Nine GPIF address lines are available in the 100 and 128 pin packages: GPIFADR[8..0]. The GPIF address lines allow indexing through up to a 512 byte block of RAM. If more address lines are needed, IO port pins are used. Long Transfer Mode In Master mode, the 8051 appropriately sets the GPIF transaction count registers (GPIFTCB3, GPIFTCB2, GPIFTCB1, or GPIFTCB0) for unattended transfers of up to 232 transactions. The GPIF automatically throttles data flow to prevent under or overflow until the full number of requested transactions are complete. The GPIF decrements the value in these registers to represent the current status of the transaction. ECC Generation The EZ-USB FX1 can calculate ECCs (Error Correcting Codes) on data that pass across its GPIF or Slave FIFO interfaces. There are two ECC configurations: Two ECCs, each calculated over 256 bytes (SmartMedia™ Standard); and one ECC calculated over 512 bytes. An 8051 register bit selects one of two frequencies for the internally supplied interface clock: 30 MHz and 48 MHz. Alternatively, an externally supplied clock of 5 - 48 MHz feeding the IFCLK pin is used as the interface clock. IFCLK is configured to function as an output clock when the GPIF and FIFOs are internally clocked. An output enable bit in the IFCONFIG register turns this clock output off, if desired. Another bit within the IFCONFIG register inverts the IFCLK signal whether internally or externally sourced. The ECC can correct any one-bit error or detect any two-bit error. GPIF Two 3-byte ECCs, each calculated over a 256-byte block of data. This configuration conforms to the SmartMedia Standard. The GPIF is a flexible 8 or 16-bit parallel interface driven by a user programmable finite state machine. It allows the CY7C64713 to perform local bus mastering, and can implement a wide variety of protocols such as ATA interface, printer parallel port, and Utopia. The GPIF has six programmable control outputs (CTL), nine address outputs (GPIFADRx), and six general purpose Ready inputs (RDY). The data bus width is 8 or 16 bits. Each GPIF vector defines the state of the control outputs, and determines Document #: 38-08039 Rev. *E Note To use the ECC logic, the GPIF or Slave FIFO interface must be configured for byte-wide operation. ECC Implementation The two ECC configurations are selected by the ECCM bit: 0.0.0.1 ECCM = 0 Write any value to ECCRESET, then pass data across the GPIF or Slave FIFO interface. The ECC for the first 256 bytes of data is calculated and stored in ECC1. The ECC for the next 256 bytes is stored in ECC2. After the second ECC is calculated, the values in the ECCx registers do not change until the ECCRESET is written again, even if more data is subsequently passed across the interface. Page 10 of 54 [+] Feedback CY7C64713 0.0.0.2 ECCM = 1 I2C Interface Boot Load Access One 3-byte ECC calculated over a 512-byte block of data. At power on reset the I2C interface boot loader loads the VID/PID/DID configuration bytes and up to 16 KBytes of program/data. The available RAM spaces are 16 KBytes from 0x0000–0x3FFF and 512 bytes from 0xE000–0xE1FF. The 8051 is in reset. I2C interface boot loads only occur after power on reset. Write any value to ECCRESET, then pass data across the GPIF or Slave FIFO interface. The ECC for the first 512 bytes of data is calculated and stored in ECC1; ECC2 is not used. After the ECC is calculated, the value in ECC1 does not change until the ECCRESET is written again, even if more data is subsequently passed across the interface USB Uploads and Downloads The core has the ability to directly edit the data contents of the internal 16 KByte RAM and of the internal 512 byte scratch pad RAM via a vendor specific command. This capability is normally used when ‘soft’ downloading user code and is available only to and from the internal RAM, only when the 8051 is held in reset. The available RAM spaces are 16 KBytes from 0x0000–0x3FFF (code/data) and 512 bytes from 0xE000–0xE1FF (scratch pad data RAM).[4] Autopointer Access FX1 provides two identical autopointers. They are similar to the internal 8051 data pointers, but with an additional feature: they can optionally increment after every memory access. This capability is available to and from both internal and external RAM. The autopointers are available in external FX1 registers, under the control of a mode bit (AUTOPTRSETUP.0). Using the external FX1 autopointer access (at 0xE67B – 0xE67C) allows the autopointer to access all RAM, internal and external, to the part. Also, the autopointers can point to any FX1 register or endpoint buffer space. When autopointer access to external memory is enabled, the location 0xE67B and 0xE67C in XDATA and the code space cannot be used. I2C Controller FX1 has one I2C port that is driven by two internal controllers: one that automatically operates at boot time to load VID/PID/DID and configuration information; and another that the 8051, once running, uses to control external I2C devices. The I2C port operates in master mode only. I2C Port Pins The I2C pins SCL and SDA must have external 2.2 kΩ pull up resistors even if no EEPROM is connected to the FX1. External EEPROM device address pins must be configured properly. See Table 7 for configuring the device address pins. Table 7. Strap Boot EEPROM Address Lines to These Values Bytes Example EEPROM A2 A1 A0 16 24LC00[5] N/A N/A N/A 128 24LC01 0 0 0 256 24LC02 0 0 0 4K 24LC32 0 0 1 8K 24LC64 0 0 1 16K 24LC128 0 0 1 I2C Interface General Purpose Access The 8051 can control peripherals connected to the I2C bus using the I2CTL and I2DAT registers. FX1 provides I2C master control only, because it is never an I2C slave. Compatible with Previous Generation EZ-USB FX2 The EZ-USB FX1 is fit, form, and function upgradable to the EZ-USB FX2LP. This makes for an easy transition for designers wanting to upgrade their systems from full speed to high speed designs. The pinout and package selection are identical, and all firmware developed for the FX1 function in the FX2LP with proper addition of high speed descriptors and speed switching code. Pin Assignments Figure 7 on page 12 identifies all signals for the three package types. The following pages illustrate the individual pin diagrams, plus a combination diagram showing which of the full set of signals are available in the 128, 100, and 56 pin packages. The signals on the left edge of the 56 pin package in Figure 7 on page 12 are common to all versions in the FX1 family. Three modes are available in all package versions: Port, GPIF master, and Slave FIFO. These modes define the signals on the right edge of the diagram. The 8051 selects the interface mode using the IFCONFIG[1:0] register bits. Port mode is the power on default configuration. The 100-pin package adds functionality to the 56 pin package by adding these pins: ■ PORTC or alternate GPIFADR[7:0] address signals ■ PORTE or alternate GPIFADR[8] address signal and seven additional 8051 signals ■ Three GPIF Control signals ■ Four GPIF Ready signals ■ Nine 8051 signals (two USARTs, three timer inputs, INT4,and INT5#) ■ BKPT, RD#, WR#. The 128 pin package adds the 8051 address and data buses plus control signals. Note that two of the required signals, RD# and WR#, are present in the 100 pin version. In the 100 pin and 128 pin versions, an 8051 control bit is set to pulse the RD# and WR# pins when the 8051 reads from and writes to the PORTC. Notes 4. After the data is downloaded from the host, a ‘loader’ executes from the internal RAM to transfer downloaded data to the external memory. 5. This EEPROM has no address pins. Document #: 38-08039 Rev. *E Page 11 of 54 [+] Feedback CY7C64713 Figure 7. Signals Port XTALIN XTALOUT RESET# WAKEUP# SCL SDA 56 GPIF Master PD7 PD6 PD5 PD4 PD3 PD2 PD1 PD0 PB7 PB6 PB5 PB4 PB3 PB2 PB1 PB0 INT0#/PA0 INT1#/PA1 PA2 WU2/PA3 PA4 PA5 PA6 PA7 IFCLK CLKOUT DPLUS DMINUS FD[15] FD[14] FD[13] FD[12] FD[11] FD[10] FD[9] FD[8] FD[7] FD[6] FD[5] FD[4] FD[3] FD[2] FD[1] FD[0] Slave FIFO FD[15] FD[14] FD[13] FD[12] FD[11] FD[10] FD[9] FD[8] FD[7] FD[6] FD[5] FD[4] FD[3] FD[2] FD[1] FD[0] RDY0 RDY1 SLRD SLWR CTL0 CTL1 CTL2 FLAGA FLAGB FLAGC INT0#/PA0 INT1#/PA1 PA2 WU2/PA3 PA4 PA5 PA6 PA7 INT0#/ PA0 INT1#/ PA1 SLOE WU2/PA3 FIFOADR0 FIFOADR1 PKTEND PA7/FLAGD/SLCS# CTL3 CTL4 CTL5 RDY2 RDY3 RDY4 RDY5 100 BKPT PORTC7/GPIFADR7 PORTC6/GPIFADR6 PORTC5/GPIFADR5 PORTC4/GPIFADR4 PORTC3/GPIFADR3 PORTC2/GPIFADR2 PORTC1/GPIFADR1 PORTC0/GPIFADR0 PE7/GPIFADR8 PE6/T2EX PE5/INT6 PE4/RxD1OUT PE3/RxD0OUT PE2/T2OUT PE1/T1OUT PE0/T0OUT 128 Document #: 38-08039 Rev. *E RD# WR# CS# OE# PSEN# D7 D6 D5 D4 D3 D2 D1 D0 EA RxD0 TxD0 RxD1 TxD1 INT4 INT5# T2 T1 T0 A15 A14 A13 A12 A11 A10 A9 A8 A7 A6 A5 A4 A3 A2 A1 A0 Page 12 of 54 [+] Feedback CY7C64713 Figure 8. CY7C64713 128 pin TQFP Pin Assignment 27 28 29 30 31 32 33 34 35 36 37 38 103 26 104 25 105 24 106 23 107 22 108 21 109 20 110 19 111 18 112 17 113 16 114 15 115 14 116 13 117 12 118 11 119 10 120 9 121 8 122 7 123 6 124 5 125 4 126 3 PD1/FD9 PD2/FD10 PD3/FD11 INT5# VCC PE0/T0OUT PE1/T1OUT PE2/T2OUT PE3/RXD0OUT PE4/RXD1OUT PE5/INT6 PE6/T2EX PE7/GPIFADR8 GND A4 A5 A6 A7 PD4/FD12 PD5/FD13 PD6/FD14 PD7/FD15 GND A8 A9 A10 2 127 128 1 CLKOUT VCC GND RDY0/*SLRD RDY1/*SLWR RDY2 RDY3 RDY4 RDY5 AVCC XTALOUT XTALIN AGND NC NC NC AVCC DPLUS DMINUS AGND A11 A12 A13 A14 A15 VCC GND INT4 T0 T1 T2 *IFCLK RESERVED BKPT EA SCL SDA OE# PD0/FD8 *WAKEUP VCC RESET# CTL5 A3 A2 A1 A0 GND PA7/*FLAGD/SLCS# PA6/*PKTEND PA5/FIFOADR1 PA4/FIFOADR0 D7 D6 D5 PA3/*WU2 PA2/*SLOE PA1/INT1# PA0/INT0# VCC GND PC7/GPIFADR7 PC6/GPIFADR6 PC5/GPIFADR5 PC4/GPIFADR4 PC3/GPIFADR3 PC2/GPIFADR2 PC1/GPIFADR1 PC0/GPIFADR0 CTL2/*FLAGC CTL1/*FLAGB CTL0/*FLAGA VCC CTL4 CTL3 GND CY7C64713 128 pin TQFP 102 101 100 99 98 97 96 95 94 93 92 91 90 89 88 87 86 85 84 83 82 81 80 79 78 77 76 75 74 73 72 71 70 69 68 67 66 65 VCC D4 D3 D2 D1 D0 GND PB7/FD7 PB6/FD6 PB5/FD5 PB4/FD4 RXD1 TXD1 RXD0 TXD0 GND VCC PB3/FD3 PB2/FD2 PB1/FD1 PB0/FD0 VCC CS# WR# RD# PSEN# 64 63 62 61 60 59 58 57 56 55 54 53 52 51 50 49 48 47 46 45 44 43 42 41 40 39 * indicates programmable polarity Document #: 38-08039 Rev. *E Page 13 of 54 [+] Feedback CY7C64713 Figure 9. CY7C64713 100 pin TQFP Pin Assignment 81 82 83 84 85 86 87 88 89 90 91 92 93 94 95 96 97 98 99 100 PD1/FD9 PD2/FD10 PD3/FD11 INT5# VCC PE0/T0OUT PE1/T1OUT PE2/T2OUT PE3/RXD0OUT PE4/RXD1OUT PE5/INT6 PE6/T2EX PE7/GPIFADR8 GND PD4/FD12 PD5/FD13 PD6/FD14 PD7/FD15 GND CLKOUT 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 VCC GND RDY0/*SLRD RDY1/*SLWR RDY2 RDY3 RDY4 RDY5 AVCC XTALOUT XTALIN AGND NC NC NC AVCC DPLUS DMINUS AGND VCC GND INT4 T0 T1 T2 *IFCLK RESERVED BKPT SCL SDA PD0/FD8 *WAKEUP VCC RESET# CTL5 GND PA7/*FLAGD/SLCS# PA6/*PKTEND PA5/FIFOADR1 PA4/FIFOADR0 PA3/*WU2 PA2/*SLOE PA1/INT1# PA0/INT0# VCC GND PC7/GPIFADR7 PC6/GPIFADR6 PC5/GPIFADR5 PC4/GPIFADR4 PC3/GPIFADR3 PC2/GPIFADR2 PC1/GPIFADR1 PC0/GPIFADR0 CTL2/*FLAGC CTL1/*FLAGB CTL0/*FLAGA VCC CTL4 CTL3 CY7C64713 100 pin TQFP 80 79 78 77 76 75 74 73 72 71 70 69 68 67 66 65 64 63 62 61 60 59 58 57 56 55 54 53 52 51 GND VCC GND PB7/FD7 PB6/FD6 PB5/FD5 PB4/FD4 RXD1 TXD1 RXD0 TXD0 GND VCC PB3/FD3 PB2/FD2 PB1/FD1 PB0/FD0 VCC WR# RD# 50 49 48 47 46 45 44 43 42 41 40 39 38 37 36 35 34 33 32 31 Document #: 38-08039 Rev. *E * indicates programmable polarity Page 14 of 54 [+] Feedback CY7C64713 Figure 10. CY7C64713 56 pin SSOP Pin Assignment CY7C64713 56 pin SSOP 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 PD5/FD13 PD6/FD14 PD7/FD15 GND CLKOUT VCC GND RDY0/*SLRD RDY1/*SLWR AVCC XTALOUT XTALIN AGND AVCC DPLUS DMINUS AGND VCC GND *IFCLK RESERVED SCL SDA VCC PB0/FD0 PB1/FD1 PB2/FD2 PB3/FD3 PD4/FD12 PD3/FD11 PD2/FD10 PD1/FD9 PD0/FD8 *WAKEUP VCC RESET# GND PA7/*FLAGD/SLCS# PA6/PKTEND PA5/FIFOADR1 PA4/FIFOADR0 PA3/*WU2 PA2/*SLOE PA1/INT1# PA0/INT0# VCC CTL2/*FLAGC CTL1/*FLAGB CTL0/*FLAGA GND VCC GND PB7/FD7 PB6/FD6 PB5/FD5 PB4/FD4 56 55 54 53 52 51 50 49 48 47 46 45 44 43 42 41 40 39 38 37 36 35 34 33 32 31 30 29 * indicates programmable polarity Document #: 38-08039 Rev. *E Page 15 of 54 [+] Feedback CY7C64713 Figure 11. CY7C64713 56 pin QFN Pin Assignment GND VCC CLKOUT GND PD7/FD15 PD6/FD14 PD5/FD13 PD4/FD12 PD3/FD11 PD2/FD10 PD1/FD9 PD0/FD8 *WAKEUP VCC 56 55 54 53 52 51 50 49 48 47 46 45 44 43 RDY0/*SLRD 1 42 RESET# RDY1/*SLWR 2 41 GND AVCC 3 40 PA7/*FLAGD/SLCS# XTALOUT 4 39 PA6/*PKTEND XTALIN 5 38 PA5/FIFOADR1 AGND 6 37 PA4/FIFOADR0 AVCC 7 36 PA3/*WU2 DPLUS 8 35 PA2/*SLOE DMINUS 9 34 PA1/INT1# AGND 10 33 PA0/INT0# VCC 11 32 VCC GND 12 31 CTL2/*FLAGC *IFCLK 13 30 CTL1/*FLAGB RESERVED 14 29 CTL0/*FLAGA CY7C64713 56 pin QFN 15 16 17 18 19 20 21 22 23 24 25 26 27 28 SCL SDA VCC PB0/FD0 PB1/FD1 PB2/FD2 PB3/FD3 PB4/FD4 PB5/FD5 PB6/FD6 PB7/FD7 GND VCC GND * indicates programmable polarity Document #: 38-08039 Rev. *E Page 16 of 54 [+] Feedback CY7C64713 CY7C64713 Pin Definitions The FX1 Pin Definitions for CY7C64713 follow.[6] Table 8. FX1 Pin Definitions 128 100 56 56 TQFP TQFP SSOP QFN Name Type Default Description 10 9 10 3 AVCC Power N/A Analog VCC. Connect this pin to 3.3V power source. This signal provides power to the analog section of the chip. 17 16 14 7 AVCC Power N/A Analog VCC. Connect this pin to 3.3V power source. This signal provides power to the analog section of the chip. 13 12 13 6 AGND Ground N/A Analog Ground. Connect to ground with as short a path as possible. N/A Analog Ground. Connect to ground with as short a path as possible. 20 19 17 10 AGND Ground 19 18 16 9 DMINUS IO/Z Z 18 17 15 8 USB D– Signal. Connect to the USB D– signal. DPLUS IO/Z Z USB D+ Signal. Connect to the USB D+ signal. 94 A0 Output L 95 A1 Output L 8051 Address Bus. This bus is driven at all times. When the 8051 is addressing the internal RAM it reflects the internal address. 96 A2 Output L 97 A3 Output L 117 A4 Output L 118 A5 Output L 119 A6 Output L 120 A7 Output L 126 A8 Output L 127 A9 Output L 128 A10 Output L 21 A11 Output L 22 A12 Output L 23 A13 Output L 24 A14 Output L 25 A15 Output L 59 D0 IO/Z Z 60 D1 IO/Z Z 61 D2 IO/Z Z 62 D3 IO/Z Z 63 D4 IO/Z Z 86 D5 IO/Z Z 87 D6 IO/Z Z 88 D7 IO/Z Z 39 PSEN# Output H Program Store Enable. This active LOW signal indicates an 8051 code fetch from external memory. It is active for program memory fetches from 0x4000–0xFFFF when the EA pin is LOW, or from 0x0000–0xFFFF when the EA pin is HIGH. BKPT Output L Breakpoint. This pin goes active (HIGH) when the 8051 address bus matches the BPADDRH/L registers and breakpoints are enabled in the BREAKPT register (BPEN = 1). If the BPPULSE bit in the BREAKPT register is HIGH, this signal pulses HIGH for eight 12-/24-/48 MHz clocks. If the BPPULSE bit is LOW, the signal remains HIGH until the 8051 clears the BREAK bit (by writing ‘1’ to it) in the BREAKPT register. 34 28 8051 Data Bus. This bidirectional bus is high impedance when inactive, input for bus reads, and output for bus writes. The data bus is used for external 8051 program and data memory. The data bus is active only for external bus accesses, and is driven LOW in suspend. Note 6. Do not leave unused inputs floating. Tie either HIGH or LOW as appropriate. Pull outputs up or down to ensure signals at power up and in standby. Note that no pins must be driven when the device is powered down. Document #: 38-08039 Rev. *E Page 17 of 54 [+] Feedback CY7C64713 Table 8. FX1 Pin Definitions (continued) 128 100 56 56 TQFP TQFP SSOP QFN 99 77 49 42 35 Name Type Default Description RESET# Input N/A Active LOW Reset. Resets the entire chip. See the section “Reset and Wakeup” on page 6 for more details. EA Input N/A External Access. This pin determines where the 8051 fetches code between addresses 0x0000 and 0x3FFF. If EA = 0 the 8051 fetches this code from its internal RAM. IF EA = 1 the 8051 fetches this code from external memory. 12 11 12 5 XTALIN Input N/A Crystal Input. Connect this signal to a 24 MHz parallel-resonant, fundamental mode crystal and load capacitor to GND. It is also correct to drive the XTALIN with an external 24 MHz square wave derived from another clock source. When driving from an external source, the driving signal must be a 3.3V square wave. 11 10 11 4 XTALOUT Output N/A Crystal Output. Connect this signal to a 24 MHz parallel-resonant, fundamental mode crystal and load capacitor to GND. If an external clock is used to drive XTALIN, leave this pin open. 1 100 5 54 CLKOUT O/Z 12 CLKOUT: 12, 24 or 48 MHz clock, phase locked to the 24 MHz input MHz clock. The 8051 defaults to 12 MHz operation. The 8051 may three-state this output by setting CPUCS.1 = 1. 82 67 40 33 PA0 or INT0# IO/Z I Multiplexed pin whose function is selected by PORTACFG.0 (PA0) PA0 is a bidirectional IO port pin. INT0# is the active-LOW 8051 INT0 interrupt input signal, which is either edge triggered (IT0 = 1) or level triggered (IT0 = 0). 83 68 41 34 PA1 or INT1# IO/Z I Multiplexed pin whose function is selected by: (PA1) PORTACFG.1 PA1 is a bidirectional IO port pin. INT1# is the active-LOW 8051 INT1 interrupt input signal, which is either edge triggered (IT1 = 1) or level triggered (IT1 = 0). 84 69 42 35 PA2 or SLOE IO/Z I Multiplexed pin whose function is selected by two bits: (PA2) IFCONFIG[1:0]. PA2 is a bidirectional IO port pin. SLOE is an input-only output enable with programmable polarity (FIFOPINPOLAR.4) for the slave FIFOs connected to FD[7..0] or FD[15..0]. 85 70 43 36 PA3 or WU2 IO/Z I Multiplexed pin whose function is selected by: (PA3) WAKEUP.7 and OEA.3 PA3 is a bidirectional IO port pin. WU2 is an alternate source for USB Wakeup, enabled by WU2EN bit (WAKEUP.1) and polarity set by WU2POL (WAKEUP.4). If the 8051 is in suspend and WU2EN = 1, a transition on this pin starts up the oscillator and interrupts the 8051 to allow it to exit the suspend mode. Asserting this pin inhibits the chip from suspending, if WU2EN = 1. 89 71 44 37 PA4 or FIFOADR0 IO/Z I Multiplexed pin whose function is selected by: (PA4) IFCONFIG[1..0]. PA4 is a bidirectional IO port pin. FIFOADR0 is an input-only address select for the slave FIFOs connected to FD[7..0] or FD[15..0]. 90 72 45 38 PA5 or FIFOADR1 IO/Z I Multiplexed pin whose function is selected by: (PA5) IFCONFIG[1..0]. PA5 is a bidirectional IO port pin. FIFOADR1 is an input-only address select for the slave FIFOs connected to FD[7..0] or FD[15..0]. Port A Document #: 38-08039 Rev. *E Page 18 of 54 [+] Feedback CY7C64713 Table 8. FX1 Pin Definitions (continued) 128 100 56 56 TQFP TQFP SSOP QFN Name Type Default Description 91 73 46 39 PA6 or PKTEND IO/Z I Multiplexed pin whose function is selected by the IFCONFIG[1:0] bits. (PA6) PA6 is a bidirectional IO port pin. PKTEND is an input used to commit the FIFO packet data to the endpoint and whose polarity is programmable via FIFOPINPOLAR.5. 92 74 47 40 PA7 or FLAGD or SLCS# IO/Z I Multiplexed pin whose function is selected by the IFCONFIG[1:0] and (PA7) PORTACFG.7 bits. PA7 is a bidirectional IO port pin. FLAGD is a programmable slave-FIFO output status flag signal. SLCS# gates all other slave FIFO enable/strobes 44 34 25 18 PB0 or FD[0] IO/Z I Multiplexed pin whose function is selected by the following bits: (PB0) IFCONFIG[1..0]. PB0 is a bidirectional IO port pin. FD[0] is the bidirectional FIFO/GPIF data bus. 45 35 26 19 PB1 or FD[1] IO/Z I Multiplexed pin whose function is selected by the following bits: (PB1) IFCONFIG[1..0]. PB1 is a bidirectional IO port pin. FD[1] is the bidirectional FIFO/GPIF data bus. 46 36 27 20 PB2 or FD[2] IO/Z I Multiplexed pin whose function is selected by the following bits: (PB2) IFCONFIG[1..0]. PB2 is a bidirectional IO port pin. FD[2] is the bidirectional FIFO/GPIF data bus. 47 37 28 21 PB3 or FD[3] IO/Z I Multiplexed pin whose function is selected by the following bits: (PB3) IFCONFIG[1..0]. PB3 is a bidirectional IO port pin. FD[3] is the bidirectional FIFO/GPIF data bus. 54 44 29 22 PB4 or FD[4] IO/Z I Multiplexed pin whose function is selected by the following bits: (PB4) IFCONFIG[1..0]. PB4 is a bidirectional IO port pin. FD[4] is the bidirectional FIFO/GPIF data bus. 55 45 30 23 PB5 or FD[5] IO/Z I Multiplexed pin whose function is selected by the following bits: (PB5) IFCONFIG[1..0]. PB5 is a bidirectional IO port pin. FD[5] is the bidirectional FIFO/GPIF data bus. 56 46 31 24 PB6 or FD[6] IO/Z I Multiplexed pin whose function is selected by the following bits: (PB6) IFCONFIG[1..0]. PB6 is a bidirectional IO port pin. FD[6] is the bidirectional FIFO/GPIF data bus. 57 47 32 25 PB7 or FD[7] IO/Z I Multiplexed pin whose function is selected by the following bits: (PB7) IFCONFIG[1..0]. PB7 is a bidirectional IO port pin. FD[7] is the bidirectional FIFO/GPIF data bus. Port B PORT C 72 57 PC0 or GPIFADR0 IO/Z I Multiplexed pin whose function is selected by PORTCCFG.0 (PC0) PC0 is a bidirectional IO port pin. GPIFADR0 is a GPIF address output pin. 73 58 PC1 or GPIFADR1 IO/Z I Multiplexed pin whose function is selected by PORTCCFG.1 (PC1) PC1 is a bidirectional IO port pin. GPIFADR1 is a GPIF address output pin. 74 59 PC2 or GPIFADR2 IO/Z I Multiplexed pin whose function is selected by PORTCCFG.2 (PC2) PC2 is a bidirectional IO port pin. GPIFADR2 is a GPIF address output pin. Document #: 38-08039 Rev. *E Page 19 of 54 [+] Feedback CY7C64713 Table 8. FX1 Pin Definitions (continued) 128 100 56 56 TQFP TQFP SSOP QFN Name Type Default Description 75 60 PC3 or GPIFADR3 IO/Z I Multiplexed pin whose function is selected by PORTCCFG.3 (PC3) PC3 is a bidirectional IO port pin. GPIFADR3 is a GPIF address output pin. 76 61 PC4 or GPIFADR4 IO/Z I Multiplexed pin whose function is selected by PORTCCFG.4 (PC4) PC4 is a bidirectional IO port pin. GPIFADR4 is a GPIF address output pin. 77 62 PC5 or GPIFADR5 IO/Z I Multiplexed pin whose function is selected by PORTCCFG.5 (PC5) PC5 is a bidirectional IO port pin. GPIFADR5 is a GPIF address output pin. 78 63 PC6 or GPIFADR6 IO/Z I Multiplexed pin whose function is selected by PORTCCFG.6 (PC6) PC6 is a bidirectional IO port pin. GPIFADR6 is a GPIF address output pin. 79 64 PC7 or GPIFADR7 IO/Z I Multiplexed pin whose function is selected by PORTCCFG.7 (PC7) PC7 is a bidirectional IO port pin. GPIFADR7 is a GPIF address output pin. PORT D 102 80 52 45 PD0 or FD[8] IO/Z I Multiplexed pin whose function is selected by the IFCONFIG[1..0] and (PD0) EPxFIFOCFG.0 (wordwide) bits. FD[8] is the bidirectional FIFO/GPIF data bus. 103 81 53 46 PD1 or FD[9] IO/Z I Multiplexed pin whose function is selected by the IFCONFIG[1..0] and (PD1) EPxFIFOCFG.0 (wordwide) bits. FD[9] is the bidirectional FIFO/GPIF data bus. 104 82 54 47 PD2 or FD[10] IO/Z I Multiplexed pin whose function is selected by the IFCONFIG[1..0] and (PD2) EPxFIFOCFG.0 (wordwide) bits. FD[10] is the bidirectional FIFO/GPIF data bus. 105 83 55 48 PD3 or FD[11] IO/Z I Multiplexed pin whose function is selected by the IFCONFIG[1..0] and (PD3) EPxFIFOCFG.0 (wordwide) bits. FD[11] is the bidirectional FIFO/GPIF data bus. 121 95 56 49 PD4 or FD[12] IO/Z I Multiplexed pin whose function is selected by the IFCONFIG[1..0] and (PD4) EPxFIFOCFG.0 (wordwide) bits. FD[12] is the bidirectional FIFO/GPIF data bus. 122 96 1 50 PD5 or FD[13] IO/Z I Multiplexed pin whose function is selected by the IFCONFIG[1..0] and (PD5) EPxFIFOCFG.0 (wordwide) bits. FD[13] is the bidirectional FIFO/GPIF data bus. 123 97 2 51 PD6 or FD[14] IO/Z I Multiplexed pin whose function is selected by the IFCONFIG[1..0] and (PD6) EPxFIFOCFG.0 (wordwide) bits. FD[14] is the bidirectional FIFO/GPIF data bus. 124 98 3 52 PD7 or FD[15] IO/Z I Multiplexed pin whose function is selected by the IFCONFIG[1..0] and (PD7) EPxFIFOCFG.0 (wordwide) bits. FD[15] is the bidirectional FIFO/GPIF data bus. PE0 or T0OUT IO/Z I Multiplexed pin whose function is selected by the PORTECFG.0 bit. (PE0) PE0 is a bidirectional IO port pin. T0OUT is an active HIGH signal from 8051 Timer-counter0. T0OUT outputs a high level for one CLKOUT clock cycle when Timer0 overflows. If Timer0 is operated in Mode 3 (two separate timer/counters), T0OUT is active when the low byte timer/counter overflows. Port E 108 86 Document #: 38-08039 Rev. *E Page 20 of 54 [+] Feedback CY7C64713 Table 8. FX1 Pin Definitions (continued) 128 100 56 56 TQFP TQFP SSOP QFN Name Type Default Description 109 87 PE1 or T1OUT IO/Z I Multiplexed pin whose function is selected by the PORTECFG.1 bit. (PE1) PE1 is a bidirectional IO port pin. T1OUT is an active HIGH signal from 8051 Timer-counter1. T1OUT outputs a high level for one CLKOUT clock cycle when Timer1 overflows. If Timer1 is operated in Mode 3 (two separate timer/counters), T1OUT is active when the low byte timer/counter overflows. 110 88 PE2 or T2OUT IO/Z I Multiplexed pin whose function is selected by the PORTECFG.2 bit. (PE2) PE2 is a bidirectional IO port pin. T2OUT is the active HIGH output signal from 8051 Timer2. T2OUT is active (HIGH) for one clock cycle when Timer/Counter 2 overflows. 111 89 PE3 or RXD0OUT IO/Z I Multiplexed pin whose function is selected by the PORTECFG.3 bit. (PE3) PE3 is a bidirectional IO port pin. RXD0OUT is an active HIGH signal from 8051 UART0. If RXD0OUT is selected and UART0 is in Mode 0, this pin provides the output data for UART0 only when it is in sync mode. Otherwise it is a 1. 112 90 PE4 or RXD1OUT IO/Z I Multiplexed pin whose function is selected by the PORTECFG.4 bit. (PE4) PE4 is a bidirectional IO port pin. RXD1OUT is an active HIGH output from 8051 UART1. When the RXD1OUT is selected and UART1 is in Mode 0, this pin provides the output data for UART1 only when it is in sync mode. In Modes 1, 2, and 3, this pin is HIGH. 113 91 PE5 or INT6 IO/Z I Multiplexed pin whose function is selected by the PORTECFG.5 bit. (PE5) PE5 is a bidirectional IO port pin. INT6 is the 8051 INT6 interrupt request input signal. The INT6 pin is edge-sensitive, active HIGH. 114 92 PE6 or T2EX IO/Z I Multiplexed pin whose function is selected by the PORTECFG.6 bit. (PE6) PE6 is a bidirectional IO port pin. T2EX is an active HIGH input signal to the 8051 Timer2. T2EX reloads timer 2 on its falling edge. T2EX is active only if the EXEN2 bit is set in T2CON. 115 93 PE7 or GPIFADR8 IO/Z I Multiplexed pin whose function is selected by the PORTECFG.7 bit. (PE7) PE7 is a bidirectional IO port pin. GPIFADR8 is a GPIF address output pin. 4 3 8 1 RDY0 or SLRD Input N/A Multiplexed pin whose function is selected by the following bits: IFCONFIG[1..0]. RDY0 is a GPIF input signal. SLRD is the input-only read strobe with programmable polarity (FIFOPINPOLAR.3) for the slave FIFOs connected to FD[7..0] or FD[15..0]. 5 4 9 2 RDY1 or SLWR Input N/A Multiplexed pin whose function is selected by the following bits: IFCONFIG[1..0]. RDY1 is a GPIF input signal. SLWR is the input-only write strobe with programmable polarity (FIFOPINPOLAR.2) for the slave FIFOs connected to FD[7..0] or FD[15..0]. 6 5 RDY2 Input N/A RDY2 is a GPIF input signal. 7 6 RDY3 Input N/A RDY3 is a GPIF input signal. 8 7 RDY4 Input N/A RDY4 is a GPIF input signal. 9 8 RDY5 Input N/A RDY5 is a GPIF input signal. Document #: 38-08039 Rev. *E Page 21 of 54 [+] Feedback CY7C64713 Table 8. FX1 Pin Definitions (continued) 128 100 56 56 TQFP TQFP SSOP QFN Name Type Default Description 69 54 36 29 CTL0 or FLAGA O/Z H Multiplexed pin whose function is selected by the following bits: IFCONFIG[1..0]. CTL0 is a GPIF control output. FLAGA is a programmable slave-FIFO output status flag signal. Defaults to programmable for the FIFO selected by the FIFOADR[1:0] pins. 70 55 37 30 CTL1 or FLAGB O/Z H Multiplexed pin whose function is selected by the following bits: IFCONFIG[1..0]. CTL1 is a GPIF control output. FLAGB is a programmable slave-FIFO output status flag signal. Defaults to FULL for the FIFO selected by the FIFOADR[1:0] pins. 71 56 38 31 CTL2 or FLAGC O/Z H Multiplexed pin whose function is selected by the following bits: IFCONFIG[1..0]. CTL2 is a GPIF control output. FLAGC is a programmable slave-FIFO output status flag signal. Defaults to EMPTY for the FIFO selected by the FIFOADR[1:0] pins. 66 51 CTL3 O/Z H CTL3 is a GPIF control output. 67 52 CTL4 Output H CTL4 is a GPIF control output. 98 76 CTL5 Output H CTL5 is a GPIF control output. 32 26 IFCLK IO/Z Z Interface Clock, used for synchronously clocking data into or out of the slave FIFOs. IFCLK also serves as a timing reference for all slave FIFO control signals and GPIF. When internal clocking is used (IFCONFIG.7 = 1) the IFCLK pin is configured to output 30/48 MHz by bits IFCONFIG.5 and IFCONFIG.6. IFCLK may be inverted, whether internally or externally sourced, by setting the bit IFCONFIG.4 = 1. 28 22 INT4 Input N/A INT4 is the 8051 INT4 interrupt request input signal. The INT4 pin is edge-sensitive, active HIGH. 106 84 INT5# Input N/A INT5# is the 8051 INT5 interrupt request input signal. The INT5 pin is edge-sensitive, active LOW. 31 25 T2 Input N/A T2 is the active-HIGH T2 input signal to 8051 Timer2, which provides the input to Timer2 when C/T2 = 1. When C/T2 = 0, Timer2 does not use this pin. 30 24 T1 Input N/A T1 is the active-HIGH T1 signal for 8051 Timer1, which provides the input to Timer1 when C/T1 is 1. When C/T1 is 0, Timer1 does not use this bit. 29 23 T0 Input N/A T0 is the active-HIGH T0 signal for 8051 Timer0, which provides the input to Timer0 when C/T0 is 1. When C/T0 is 0, Timer0 does not use this bit. 53 43 RXD1 Input N/A RXD1is an active-HIGH input signal for 8051 UART1, which provides data to the UART in all modes. 52 42 TXD1 Output H TXD1is an active-HIGH output pin from 8051 UART1, which provides the output clock in sync mode, and the output data in async mode. 51 41 RXD0 Input N/A RXD0 is the active-HIGH RXD0 input to 8051 UART0, which provides data to the UART in all modes. 50 40 TXD0 Output H TXD0 is the active-HIGH TXD0 output from 8051 UART0, which provides the output clock in sync mode, and the output data in async mode. CS# Output H CS# is the active-LOW chip select for external memory. 41 32 WR# Output H WR# is the active-LOW write strobe output for external memory. 40 31 RD# Output H RD# is the active-LOW read strobe output for external memory. OE# Output H OE# is the active LOW output enable for external memory. 42 38 20 13 Document #: 38-08039 Rev. *E Page 22 of 54 [+] Feedback CY7C64713 Table 8. FX1 Pin Definitions (continued) 128 100 56 56 TQFP TQFP SSOP QFN Name Type Default Description 33 27 21 14 Reserved Input N/A Reserved. Connect to ground. 101 79 51 44 WAKEUP Input N/A USB Wakeup. If the 8051 is in suspend, asserting this pin starts up the oscillator and interrupts the 8051 to allow it to exit the suspend mode. Holding WAKEUP asserted inhibits the EZ-USB FX1 chip from suspending. This pin has programmable polarity (WAKEUP.4). 36 29 22 15 SCL OD Z Clock for the I2C interface. Connect to VCC with a 2.2K resistor, even if no I2C peripheral is attached. 37 30 23 16 SDA OD Z Data for I2C interface. Connect to VCC with a 2.2K resistor, even if no I2C peripheral is attached. 2 1 6 55 VCC Power N/A VCC. Connect to 3.3V power source. 26 20 18 11 VCC Power N/A VCC. Connect to 3.3V power source. 43 33 24 17 VCC Power N/A VCC. Connect to 3.3V power source. 48 38 VCC Power N/A VCC. Connect to 3.3V power source. 64 49 VCC Power N/A VCC. Connect to 3.3V power source. 68 53 VCC Power N/A VCC. Connect to 3.3V power source. 34 27 81 66 39 32 VCC Power N/A VCC. Connect to 3.3V power source. 100 78 50 43 VCC Power N/A VCC. Connect to 3.3V power source. 107 85 VCC Power N/A VCC. Connect to 3.3V power source. 3 2 7 56 GND Ground N/A Ground. 27 21 19 12 GND Ground N/A Ground. 49 39 GND Ground N/A Ground. 58 48 33 26 GND Ground N/A Ground. 65 50 35 28 GND Ground N/A Ground. 80 65 GND Ground N/A Ground. GND Ground N/A Ground. GND Ground N/A Ground. GND Ground N/A Ground. 93 75 116 94 125 99 48 4 41 53 14 13 NC N/A N/A No Connect. This pin must be left open. 15 14 NC N/A N/A No Connect. This pin must be left open. 16 15 NC N/A N/A No Connect. This pin must be left open. Document #: 38-08039 Rev. *E Page 23 of 54 [+] Feedback CY7C64713 Register Summary FX1 register bit definitions are described in the EZ-USB TRM in greater detail. Table 9. FX1 Register Summary Hex Size Name Description b7 b6 b5 b4 b3 b2 b1 b0 Default Access D6 D5 D4 D3 D2 D1 D0 xxxxxxxx RW 0 3048MHZ PORTCSTB CLKSPD1 IFCLKOE IFCLKPOL CLKSPD0 ASYNC CLKINV GSTATE CLKOE IFCFG1 8051RES IFCFG0 00000010 rrbbbbbr 10000000 RW FLAGB2 FLAGB1 FLAGB0 FLAGA3 FLAGA2 FLAGA1 FLAGA0 00000000 RW FLAGD2 FLAGD1 FLAGD0 FLAGC3 FLAGC2 FLAGC1 FLAGC0 00000000 RW 0 0 0 EP3 EP2 EP1 EP0 xxxxxxxx 0 A14 0 A13 0 A12 BREAK A11 BPPULSE A10 BPEN A9 0 A8 00000000 rrrrbbbr xxxxxxxx RW A7 0 A6 0 A5 0 A4 0 A3 0 A2 0 A1 230UART1 A0 230UART0 xxxxxxxx RW 00000000 rrrrrrbb 0 0 PKTEND SLOE SLRD SLWR EF FF 00000000 rrbbbbbb rv7 rv6 rv5 rv4 rv3 rv2 rv1 rv0 0 0 0 0 0 0 dyn_out enh_pkt RevA R 00000001 00000000 rrrrrrbb 0 0 0 0 0 0 HOLDTIME1 HOLDTIME0 00000000 rrrrrrbb VALID 0 TYPE1 TYPE0 0 0 0 0 10100000 brbbrrrr VALID 0 TYPE1 TYPE0 0 0 0 0 10100000 brbbrrrr VALID VALID VALID VALID DIR DIR DIR DIR TYPE1 TYPE1 TYPE1 TYPE1 TYPE0 TYPE0 TYPE0 TYPE0 SIZE 0 SIZE 0 0 0 0 0 BUF1 0 BUF1 0 BUF0 0 BUF0 0 10100010 10100000 11100010 11100000 0 INFM1 OEP1 AUTOOUT AUTOIN ZEROLENIN 0 WORDWIDE 00000101 rbbbbbrb 0 INFM1 OEP1 AUTOOUT AUTOIN ZEROLENIN 0 WORDWIDE 00000101 rbbbbbrb 0 INFM1 OEP1 AUTOOUT AUTOIN ZEROLENIN 0 WORDWIDE 00000101 rbbbbbrb 0 INFM1 OEP1 AUTOOUT AUTOIN ZEROLENIN 0 WORDWIDE 00000101 rbbbbbrb 0 0 0 0 0 PL10 PL9 PL8 00000010 rrrrrbbb PL7 PL6 PL5 PL4 PL3 PL2 PL1 PL0 00000000 RW 0 0 0 0 0 0 PL9 PL8 00000010 rrrrrrbb PL7 PL6 PL5 PL4 PL3 PL2 PL1 PL0 00000000 RW 0 0 0 0 0 PL10 PL9 PL8 00000010 rrrrrbbb PL7 PL6 PL5 PL4 PL3 PL2 PL1 PL0 00000000 RW 0 0 0 0 0 0 PL9 PL8 00000010 rrrrrrbb PL7 PL6 PL5 PL4 PL3 PL2 PL1 PL0 00000000 RW 0 x LINE15 LINE7 COL5 LINE15 LINE7 0 x LINE14 LINE6 COL4 LINE14 LINE6 0 x LINE13 LINE5 COL3 LINE13 LINE5 0 x LINE12 LINE4 COL2 LINE12 LINE4 0 x LINE11 LINE3 COL1 LINE11 LINE3 0 x LINE10 LINE2 COL0 LINE10 LINE2 0 x LINE9 LINE1 LINE17 LINE9 LINE1 ECCM x LINE8 LINE0 LINE16 LINE8 LINE0 00000000 00000000 11111111 11111111 11111111 11111111 11111111 GPIF Waveform Memories E400 128 WAVEDATA GPIF Waveform D7 Descriptor 0, 1, 2, 3 data E480 128 reserved GENERAL CONFIGURATION E600 1 CPUCS CPU Control & Status 0 E601 1 IFCONFIG Interface Configuration IFCLKSRC (Ports, GPIF, slave FIFOs) E602 1 PINFLAGSAB[7] Slave FIFO FLAGA and FLAGB3 FLAGB Pin Configuration [7] E603 1 PINFLAGSCD Slave FIFO FLAGC and FLAGD3 FLAGD Pin Configuration [7] E604 1 FIFORESET Restore FIFOS to default NAKALL state E605 1 BREAKPT Breakpoint Control 0 E606 1 BPADDRH Breakpoint Address H A15 E607 1 E608 1 BPADDRL UART230 E609 1 FIFOPINPOLAR[7] E60A 1 REVID E60B 1 REVCTL[7] Chip Revision Control UDMA GPIFHOLDAMOUNT MSTB Hold Time (for UDMA) reserved E60C 1 3 E610 1 E611 1 E612 E613 E614 E615 1 1 1 1 2 E618 1 E619 1 E61A 1 E61B 1 E61C 4 E620 1 E621 1 E622 1 E623 1 E624 1 E625 1 E626 1 E627 1 E628 E629 E62A E62B E62C E62D E62E 1 1 1 1 1 1 1 Breakpoint Address L 230 Kbaud internally generated ref. clock Slave FIFO Interface pins polarity Chip Revision ENDPOINT CONFIGURATION EP1OUTCFG Endpoint 1-OUT Configuration EP1INCFG Endpoint 1-IN Configuration EP2CFG Endpoint 2 Configuration EP4CFG Endpoint 4 Configuration EP6CFG Endpoint 6 Configuration EP8CFG Endpoint 8 Configuration reserved EP2FIFOCFG[7] Endpoint 2 / slave FIFO configuration EP4FIFOCFG[7] Endpoint 4 / slave FIFO configuration [7] EP6FIFOCFG Endpoint 6 / slave FIFO configuration [7] EP8FIFOCFG Endpoint 8 / slave FIFO configuration reserved EP2AUTOINLENH[7] Endpoint 2 AUTOIN Packet Length H EP2AUTOINLENL[7] Endpoint 2 AUTOIN Packet Length L EP4AUTOINLENH[7] Endpoint 4 AUTOIN Packet Length H EP4AUTOINLENL[7] Endpoint 4 AUTOIN Packet Length L EP6AUTOINLENH[7] Endpoint 6 AUTOIN Packet Length H EP6AUTOINLENL[7] Endpoint 6 AUTOIN Packet Length L EP8AUTOINLENH[7] Endpoint 8 AUTOIN Packet Length H EP8AUTOINLENL[7] Endpoint 8 AUTOIN Packet Length L ECCCFG ECC Configuration ECCRESET ECC Reset ECC1B0 ECC1 Byte 0 Address ECC1B1 ECC1 Byte 1 Address ECC1B2 ECC1 Byte 2 Address ECC2B0 ECC2 Byte 0 Address ECC2B1 ECC2 Byte 1 Address W bbbbbrbb bbbbrrrr bbbbbrbb bbbbrrrr rrrrrrrb W R R R R R Note 4. 7. Read and writes to these register may require synchronization delay, see the section “Synchronization Delay” in the EZ-USB TRM. Document #: 38-08039 Rev. *E Page 24 of 54 [+] Feedback CY7C64713 Table 9. FX1 Register Summary (continued) Hex Size Name E62F 1 ECC2B2 Description ECC2 Byte 2 Address b7 COL5 b6 COL4 b5 COL3 Endpoint 2 / slave FIFO DECIS Programmable Flag H ISO Mode Endpoint 2 / slave FIFO DECIS Programmable Flag H Non-ISO Mode PKTSTAT b4 COL2 b3 COL1 b2 COL0 b1 0 b0 0 Default 11111111 Access R IN: PKTS[2] IN: PKTS[1] IN: PKTS[0] 0 OUT:PFC12 OUT:PFC11 OUT:PFC10 PFC9 PFC8 10001000 bbbbbrbb PKTSTAT OUT:PFC12 OUT:PFC11 OUT:PFC10 0 PFC9 IN:PKTS[2] OUT:PFC8 10001000 bbbbbrbb IN:PKTS[0] OUT:PFC6 PFC5 PFC4 PFC1 PFC0 00000000 RW PKTSTAT 0 IN: PKTS[1] IN: PKTS[0] 0 OUT:PFC10 OUT:PFC9 0 PFC8 10001000 bbrbbrrb PKTSTAT 0 OUT:PFC10 OUT:PFC9 0 0 PFC8 10001000 bbrbbrrb PFC4 PFC1 PFC0 00000000 RW E630 1 EP2FIFOPFH[7] E630 1 EP2FIFOPFH[7] E631 1 EP2FIFOPFL[7] Endpoint 2 / slave FIFO Programmable Flag L E632 1 EP4FIFOPFH[7] E632 1 EP4FIFOPFH[7] Endpoint 4 / slave FIFO DECIS Programmable Flag H ISO Mode Endpoint 4 / slave FIFO DECIS Programmable Flag H Non-ISO Mode E633 1 EP4FIFOPFL[7] Endpoint 4 / slave FIFO Programmable Flag L E634 1 EP6FIFOPFH[7] PKTSTAT INPKTS[2] IN: PKTS[1] IN: PKTS[0] 0 OUT:PFC12 OUT:PFC11 OUT:PFC10 PFC9 PFC8 00001000 bbbbbrbb E634 1 EP6FIFOPFH[7] Endpoint 6 / slave FIFO DECIS Programmable Flag H ISO Mode Endpoint 6 / slave FIFO DECIS Programmable Flag H Non-ISO Mode PKTSTAT OUT:PFC12 OUT:PFC11 OUT:PFC10 0 PFC9 IN:PKTS[2] OUT:PFC8 00001000 bbbbbrbb E635 1 EP6FIFOPFL[7] Endpoint 6 / slave FIFO Programmable Flag L IN:PKTS[0] OUT:PFC6 PFC5 PFC4 PFC1 PFC0 00000000 RW E636 1 EP8FIFOPFH[7] PKTSTAT 0 IN: PKTS[1] IN: PKTS[0] 0 OUT:PFC10 OUT:PFC9 0 PFC8 00001000 bbrbbrrb E636 1 EP8FIFOPFH[7] Endpoint 8 / slave FIFO DECIS Programmable Flag H ISO Mode Endpoint 8 / slave FIFO DECIS Programmable Flag H Non-ISO Mode PKTSTAT 0 OUT:PFC10 OUT:PFC9 0 0 PFC8 00001000 bbrbbrrb E637 1 EP8FIFOPFL[7] ISO Mode EP8FIFOPFL[7] Non-ISO Mode reserved reserved reserved reserved reserved reserved INPKTEND[7] OUTPKTEND[7] INTERRUPTS EP2FIFOIE[7] Endpoint 8 / slave FIFO Programmable Flag L Endpoint 8 / slave FIFO Programmable Flag L PFC7 PFC6 PFC5 PFC4 PFC3 PFC2 PFC1 PFC0 00000000 RW IN: PKTS[1] IN: PKTS[0] PFC5 OUT:PFC7 OUT:PFC6 PFC4 PFC3 PFC2 PFC1 PFC0 00000000 RW Force IN Packet End Force OUT Packet End Skip Skip 0 0 0 0 0 0 EP3 EP3 EP2 EP2 EP1 EP1 EP0 EP0 xxxxxxxx xxxxxxxx Endpoint 2 slave FIFO Flag Interrupt Enable Endpoint 2 slave FIFO Flag Interrupt Request Endpoint 4 slave FIFO Flag Interrupt Enable Endpoint 4 slave FIFO Flag Interrupt Request Endpoint 6 slave FIFO Flag Interrupt Enable Endpoint 6 slave FIFO Flag Interrupt Request Endpoint 8 slave FIFO Flag Interrupt Enable Endpoint 8 slave FIFO Flag Interrupt Request IN-BULK-NAK Interrupt Enable 0 0 0 0 EDGEPF PF EF FF 00000000 RW 0 0 0 0 0 PF EF FF 00000111 rrrrrbbb 0 0 0 0 EDGEPF PF EF FF 00000000 RW 0 0 0 0 0 PF EF FF 00000111 rrrrrbbb 0 0 0 0 EDGEPF PF EF FF 00000000 RW 0 0 0 0 0 PF EF FF 00000110 rrrrrbbb 0 0 0 0 EDGEPF PF EF FF 00000000 RW 0 0 0 0 0 PF EF FF 00000110 rrrrrbbb 0 0 EP8 EP6 EP4 EP2 EP1 EP0 00000000 RW E637 1 E640 E641 E642 E643 E644 E648 E649 8 1 1 1 1 4 1 7 E650 1 [7,8] E651 1 EP2FIFOIRQ E652 1 [7] EP4FIFOIE E653 1 EP4FIFOIRQ[7,8] E654 1 EP6FIFOIE[7] E655 1 EP6FIFOIRQ[7,8] E656 1 EP8FIFOIE[7] E657 1 EP8FIFOIRQ[7,8] E658 1 IBNIE IN:PKTS[1] OUT:PFC7 IN: PKTS[1] IN: PKTS[0] PFC5 OUT:PFC7 OUT:PFC6 IN:PKTS[1] OUT:PFC7 PFC3 PFC3 PFC3 PFC2 PFC2 PFC2 W W Note 8. SFRs not part of the standard 8051 architecture. 9. The register can only be reset. It cannot be set. Document #: 38-08039 Rev. *E Page 25 of 54 [+] Feedback CY7C64713 Table 9. FX1 Register Summary (continued) Hex Size Name E659 1 IBNIRQ[8] E65A 1 NAKIE E65B 1 NAKIRQ[8] E65C 1 E65D 1 E65E 1 USBIE USBIRQ[8] EPIE E65F 1 EPIRQ[8] E660 1 E661 1 E662 1 GPIFIE[7] GPIFIRQ[7] USBERRIE E663 1 USBERRIRQ[8] E664 1 ERRCNTLIM E665 1 E666 1 CLRERRCNT INT2IVEC E667 1 INT4IVEC E668 1 E669 7 E670 1 INTSETUP reserved INPUT / OUTPUT PORTACFG E671 1 PORTCCFG E672 1 PORTECFG E673 4 E677 1 E678 1 XTALINSRC reserved I2CS E679 1 I2DAT E67A 1 I2CTL E67B 1 XAUTODAT1 E67C 1 XAUTODAT2 E67D 1 E67E 1 E67F 1 E680 E681 E682 E683 E684 E685 E686 E687 E688 1 1 1 1 1 1 1 1 2 UDMA CRC UDMACRCH[7] UDMACRCL[7] UDMACRCQUALIFIER USB CONTROL USBCS SUSPEND WAKEUPCS TOGCTL USBFRAMEH USBFRAMEL reserved FNADDR reserved E68A 1 E68B 1 ENDPOINTS EP0BCH[7] EP0BCL[7] E68C 1 E68D 1 reserved EP1OUTBC E68E E68F E690 E691 E692 E694 reserved EP1INBC EP2BCH[7] EP2BCL[7] reserved EP4BCH[7] 1 1 1 1 2 1 Description b7 IN-BULK-NAK interrupt 0 Request Endpoint Ping-NAK / IBN EP8 Interrupt Enable b6 0 b5 EP8 b4 EP6 b3 EP4 b2 EP2 b1 EP1 b0 EP0 Default Access 00xxxxxx rrbbbbbb EP6 EP4 EP2 EP1 EP0 0 IBN 00000000 RW Endpoint Ping-NAK / IBN Interrupt Request USB Int Enables USB Interrupt Requests Endpoint Interrupt Enables Endpoint Interrupt Requests GPIF Interrupt Enable GPIF Interrupt Request USB Error Interrupt Enables USB Error Interrupt Requests USB Error counter and limit EP8 EP6 EP4 EP2 EP1 EP0 0 IBN xxxxxx0x bbbbbbrb 0 0 EP8 EP0ACK EP0ACK EP6 0 0 EP4 URES URES EP2 SUSP SUSP EP1OUT SUTOK SUTOK EP1IN SOF SOF EP0OUT SUDAV SUDAV EP0IN 00000000 RW 0xxxxxxx rbbbbbbb 00000000 RW EP8 EP6 EP4 EP2 EP1OUT EP1IN EP0OUT EP0IN 0 0 0 ISOEP8 0 0 ISOEP6 0 0 ISOEP4 0 0 ISOEP2 0 0 0 0 0 0 GPIFWF GPIFWF 0 GPIFDONE 00000000 RW GPIFDONE 000000xx RW ERRLIMIT 00000000 RW ISOEP8 ISOEP6 ISOEP4 ISOEP2 0 0 0 ERRLIMIT 0000000x bbbbrrrb EC3 EC2 EC1 EC0 LIMIT3 LIMIT2 LIMIT1 LIMIT0 xxxx0100 rrrrbbbb Clear Error Counter EC3:0 x Interrupt 2 (USB) 0 Autovector Interrupt 4 (slave FIFO & 1 GPIF) Autovector Interrupt 2&4 setup 0 x I2V4 x I2V3 x I2V2 x I2V1 x I2V0 x 0 x 0 xxxxxxxx W 00000000 R 0 I4V3 I4V2 I4V1 I4V0 0 0 10000000 R 0 0 0 AV2EN 0 INT4SRC AV4EN 00000000 RW I/O PORTA Alternate Configuration I/O PORTC Alternate Configuration I/O PORTE Alternate Configuration XTALIN Clock Source FLAGD SLCS 0 0 0 0 INT1 INT0 00000000 RW GPIFA7 GPIFA6 GPIFA5 GPIFA4 GPIFA3 GPIFA2 GPIFA1 GPIFA0 00000000 RW GPIFA8 T2EX INT6 RXD1OUT RXD0OUT T2OUT T1OUT T0OUT 00000000 RW 0 0 0 0 0 0 0 EXTCLK 00000000 rrrrrrrb I²C Bus Control & Status I²C Bus Data I²C Bus Control Autoptr1 MOVX access, when APTREN=1 Autoptr2 MOVX access, when APTREN=1 START STOP LASTRD ID1 ID0 BERR ACK DONE 000xx000 bbbrrrrr d7 d6 d5 d4 d3 d2 d1 d0 xxxxxxxx 0 0 0 0 0 0 STOPIE 400KHZ 00000000 RW D7 D6 D5 D4 D3 D2 D1 D0 xxxxxxxx RW D7 D6 D5 D4 D3 D2 D1 D0 xxxxxxxx RW UDMA CRC MSB UDMA CRC LSB UDMA CRC Qualifier CRC15 CRC7 QENABLE CRC14 CRC6 0 CRC13 CRC5 0 CRC12 CRC4 0 CRC11 CRC3 QSTATE CRC10 CRC2 QSIGNAL2 CRC9 CRC8 CRC1 CRC0 QSIGNAL1 QSIGNAL0 01001010 RW 10111010 RW 00000000 brrrbbbb USB Control & Status Put chip into suspend Wakeup Control & Status Toggle Control USB Frame count H USB Frame count L 0 x WU2 Q 0 FC7 0 x WU S 0 FC6 0 x WU2POL R 0 FC5 0 x WUPOL IO 0 FC4 DISCON x 0 EP3 0 FC3 NOSYNSOF x DPEN EP2 FC10 FC2 RENUM x WU2EN EP1 FC9 FC1 SIGRSUME x WUEN EP0 FC8 FC0 x0000000 xxxxxxxx xx000101 x0000000 00000xxx xxxxxxxx USB Function address 0 FA6 FA5 FA4 FA3 FA2 FA1 FA0 0xxxxxxx R Endpoint 0 Byte Count H (BC15) Endpoint 0 Byte Count L (BC7) (BC14) BC6 (BC13) BC5 (BC12) BC4 (BC11) BC3 (BC10) BC2 (BC9) BC1 (BC8) BC0 xxxxxxxx xxxxxxxx RW RW Endpoint 1 OUT Byte Count BC6 BC5 BC4 BC3 BC2 BC1 BC0 xxxxxxxx RW Endpoint 1 IN Byte Count 0 Endpoint 2 Byte Count H 0 Endpoint 2 Byte Count L BC7/SKIP BC6 0 BC6 BC5 0 BC5 BC4 0 BC4 BC3 0 BC3 BC2 BC10 BC2 BC1 BC9 BC1 BC0 BC8 BC0 xxxxxxxx xxxxxxxx xxxxxxxx RW RW RW Endpoint 4 Byte Count H 0 0 0 0 0 0 BC9 BC8 xxxxxxxx RW Document #: 38-08039 Rev. *E 0 RW RW rrrrbbbb W bbbbrbbb rrrbbbbb R R Page 26 of 54 [+] Feedback CY7C64713 Table 9. FX1 Register Summary (continued) Hex E695 E696 E698 Size 1 2 1 Name EP4BCL[7] reserved EP6BCH[7] Description b7 Endpoint 4 Byte Count L BC7/SKIP b6 BC6 b5 BC5 b4 BC4 b3 BC3 b2 BC2 b1 BC1 b0 BC0 Default xxxxxxxx Access RW Endpoint 6 Byte Count H 0 0 0 0 0 BC10 BC9 BC8 xxxxxxxx RW E699 E69A E69C E69D E69E E6A0 1 2 1 1 2 1 EP6BCL[7] reserved EP8BCH[7] EP8BCL[7] reserved EP0CS Endpoint 6 Byte Count L BC7/SKIP BC6 BC5 BC4 BC3 BC2 BC1 BC0 xxxxxxxx RW Endpoint 8 Byte Count H 0 Endpoint 8 Byte Count L BC7/SKIP 0 BC6 0 BC5 0 BC4 0 BC3 0 BC2 BC9 BC1 BC8 BC0 xxxxxxxx xxxxxxxx RW RW Endpoint 0 Control and Status Endpoint 1 OUT Control and Status Endpoint 1 IN Control and Status Endpoint 2 Control and Status Endpoint 4 Control and Status Endpoint 6 Control and Status HSNAK 0 0 0 0 0 BUSY STALL 10000000 bbbbbbrb 0 0 0 0 0 0 BUSY STALL 00000000 bbbbbbrb 0 0 0 0 0 0 BUSY STALL 00000000 bbbbbbrb 0 NPAK2 NPAK1 NPAK0 FULL EMPTY 0 STALL 00101000 rrrrrrrb 0 0 NPAK1 NPAK0 FULL EMPTY 0 STALL 00101000 rrrrrrrb 0 E6A1 1 EP1OUTCS E6A2 1 EP1INCS E6A3 1 EP2CS E6A4 1 EP4CS E6A5 1 EP6CS E6A6 1 EP8CS E6A7 1 EP2FIFOFLGS E6A8 1 EP4FIFOFLGS E6A9 1 EP6FIFOFLGS E6AA 1 EP8FIFOFLGS E6AB 1 EP2FIFOBCH E6AC 1 EP2FIFOBCL E6AD 1 EP4FIFOBCH E6AE 1 EP4FIFOBCL E6AF 1 EP6FIFOBCH E6B0 1 EP6FIFOBCL E6B1 1 EP8FIFOBCH E6B2 1 EP8FIFOBCL E6B3 1 SUDPTRH E6B4 1 SUDPTRL E6B5 1 SUDPTRCTL 2 E6B8 8 reserved SETUPDAT E6C0 1 E6C1 1 GPIF GPIFWFSELECT GPIFIDLECS E6C2 E6C3 E6C4 E6C5 1 1 1 1 E6C6 1 GPIFIDLECTL GPIFCTLCFG GPIFADRH[7] GPIFADRL[7] FLOWSTATE FLOWSTATE E6C7 1 E6C8 1 FLOWLOGIC FLOWEQ0CTL NPAK2 NPAK1 NPAK0 FULL EMPTY 0 STALL 00000100 rrrrrrrb Endpoint 8 Control and 0 Status Endpoint 2 slave FIFO 0 Flags Endpoint 4 slave FIFO 0 Flags Endpoint 6 slave FIFO 0 Flags Endpoint 8 slave FIFO 0 Flags Endpoint 2 slave FIFO 0 total byte count H Endpoint 2 slave FIFO BC7 total byte count L Endpoint 4 slave FIFO 0 total byte count H Endpoint 4 slave FIFO BC7 total byte count L Endpoint 6 slave FIFO 0 total byte count H Endpoint 6 slave FIFO BC7 total byte count L Endpoint 8 slave FIFO 0 total byte count H Endpoint 8 slave FIFO BC7 total byte count L Setup Data Pointer high A15 address byte Setup Data Pointer low ad- A7 dress byte Setup Data Pointer Auto 0 Mode 0 NPAK1 NPAK0 FULL EMPTY 0 STALL 00000100 rrrrrrrb 0 0 0 0 PF EF FF 00000010 R 0 0 0 0 PF EF FF 00000010 R 0 0 0 0 PF EF FF 00000110 R 0 0 0 0 PF EF FF 00000110 R 0 0 BC12 BC11 BC10 BC9 BC8 00000000 R BC6 BC5 BC4 BC3 BC2 BC1 BC0 00000000 R 0 0 0 0 BC10 BC9 BC8 00000000 R BC6 BC5 BC4 BC3 BC2 BC1 BC0 00000000 R 0 0 0 BC11 BC10 BC9 BC8 00000000 R BC6 BC5 BC4 BC3 BC2 BC1 BC0 00000000 R 0 0 0 0 BC10 BC9 BC8 00000000 R BC6 BC5 BC4 BC3 BC2 BC1 BC0 00000000 R A14 A13 A12 A11 A10 A9 A8 xxxxxxxx A6 A5 A4 A3 A2 A1 0 xxxxxxx0 bbbbbbbr 0 0 0 0 0 0 SDPAUTO 00000001 RW 8 bytes of setup data D7 SETUPDAT[0] = bmRequestType SETUPDAT[1] = bmRequest SETUPDAT[2:3] = wValue SETUPDAT[4:5] = wIndex SETUPDAT[6:7] = wLength D6 D5 D4 D3 D2 D1 D0 xxxxxxxx RW R Waveform Selector GPIF Done, GPIF IDLE drive mode Inactive Bus, CTL states CTL Drive Type GPIF Address H GPIF Address L SINGLEWR1 SINGLEWR0 SINGLERD1 SINGLERD0 FIFOWR1 DONE 0 0 0 0 FIFOWR0 0 FIFORD1 0 FIFORD0 IDLEDRV 11100100 RW 10000000 RW 0 TRICTL 0 GPIFA7 0 0 0 GPIFA6 CTL5 CTL5 0 GPIFA5 CTL4 CTL4 0 GPIFA4 CTL3 CTL3 0 GPIFA3 CTL2 CTL2 0 GPIFA2 CTL1 CTL1 0 GPIFA1 CTL0 CTL0 GPIFA8 GPIFA0 11111111 00000000 00000000 00000000 Flowstate Enable and Selector Flowstate Logic CTL-Pin States in Flowstate (when Logic = 0) FSE 0 0 0 0 FS2 FS1 FS0 00000000 brrrrbbb LFUNC1 CTL0E3 LFUNC0 CTL0E2 TERMA2 CTL0E1/ CTL5 TERMA1 CTL0E0/ CTL4 TERMA0 CTL3 TERMB2 CTL2 TERMB1 CTL1 TERMB0 CTL0 00000000 RW 00000000 RW Document #: 38-08039 Rev. *E RW RW RW RW Page 27 of 54 [+] Feedback CY7C64713 Table 9. FX1 Register Summary (continued) Hex Size Name E6C9 1 FLOWEQ1CTL E6CA 1 FLOWHOLDOFF E6CB 1 FLOWSTB E6CC 1 FLOWSTBEDGE E6CD 1 E6CE 1 FLOWSTBPERIOD GPIFTCB3[7] E6CF 1 GPIFTCB2[7] E6D0 1 GPIFTCB1[7] E6D1 1 GPIFTCB0[7] 2 Description CTL-Pin States in Flowstate (when Logic = 1) Holdoff Configuration b7 CTL0E3 b5 b4 b3 CTL0E1/ CTL0E0/ CTL3 CTL5 CTL4 HOPERIOD3 HOPERIOD2 HOPERIOD1 HOPERIOD HOSTATE 0 Flowstate Strobe SLAVE Configuration Flowstate Rising/Falling 0 Edge Configuration Master-Strobe Half-Period D7 GPIF Transaction Count TC31 Byte 3 GPIF Transaction Count TC23 Byte 2 GPIF Transaction Count TC15 Byte 1 GPIF Transaction Count TC7 Byte 0 b6 CTL0E2 b2 CTL2 b1 CTL1 b0 CTL0 Default Access 00000000 RW HOCTL2 HOCTL1 HOCTL0 00000000 RW RDYASYNC CTLTOGL SUSTAIN 0 MSTB2 MSTB1 MSTB0 00100000 RW 0 0 0 0 0 FALLING RISING 00000001 rrrrrrbb D6 TC30 D5 TC29 D4 TC28 D3 TC27 D2 TC26 D1 TC25 D0 TC24 00000010 RW 00000000 RW TC22 TC21 TC20 TC19 TC18 TC17 TC16 00000000 RW TC14 TC13 TC12 TC11 TC10 TC9 TC8 00000000 RW TC6 TC5 TC4 TC3 TC2 TC1 TC0 00000001 RW reserved reserved reserved 00000000 RW EP2GPIFFLGSEL[7] Endpoint 2 GPIF Flag select EP2GPIFPFSTOP Endpoint 2 GPIF stop transaction on prog. flag EP2GPIFTRIG[7] Endpoint 2 GPIF Trigger reserved reserved reserved EP4GPIFFLGSEL[7] Endpoint 4 GPIF Flag select EP4GPIFPFSTOP Endpoint 4 GPIF stop transaction on GPIF Flag EP4GPIFTRIG[7] Endpoint 4 GPIF Trigger reserved reserved reserved EP6GPIFFLGSEL[7] Endpoint 6 GPIF Flag select EP6GPIFPFSTOP Endpoint 6 GPIF stop transaction on prog. flag EP6GPIFTRIG[7] Endpoint 6 GPIF Trigger reserved reserved reserved EP8GPIFFLGSEL[7] Endpoint 8 GPIF Flag select EP8GPIFPFSTOP Endpoint 8 GPIF stop transaction on prog. flag EP8GPIFTRIG[7] Endpoint 8 GPIF Trigger reserved XGPIFSGLDATH GPIF Data H (16-bit mode only) XGPIFSGLDATLX Read/Write GPIF Data L & trigger transaction XGPIFSGLDATLRead GPIF Data L, no NOX transaction trigger GPIFREADYCFG Internal RDY, Sync/Async, RDY pin states 0 0 0 0 0 0 FS1 FS0 0 0 0 0 0 0 0 FIFO2FLAG 00000000 RW x x x x x x x x xxxxxxxx 0 0 0 0 0 0 FS1 FS0 00000000 RW 0 0 0 0 0 0 0 FIFO4FLAG 00000000 RW x x x x x x x x xxxxxxxx 0 0 0 0 0 0 FS1 FS0 00000000 RW 0 0 0 0 0 0 0 FIFO6FLAG 00000000 RW x x x x x x x x xxxxxxxx 0 0 0 0 0 0 FS1 FS0 00000000 RW 0 0 0 0 0 0 0 FIFO8FLAG 00000000 RW x x x x x x x x xxxxxxxx W D15 D14 D13 D12 D11 D10 D9 D8 xxxxxxxx RW D7 D6 D5 D4 D3 D2 D1 D0 xxxxxxxx RW D7 D6 D5 D4 D3 D2 D1 D0 xxxxxxxx R INTRDY SAS TCXRDY5 0 0 0 0 0 00000000 bbbrrrrr E6F4 1 E6F5 1 E6F6 2 0 x 0 x RDY5 x RDY4 x RDY3 x RDY2 x RDY1 x RDY0 x 00xxxxxx R xxxxxxxx W E740 E780 E7C0 GPIFREADYSTAT GPIF Ready Status GPIFABORT Abort GPIF Waveforms reserved ENDPOINT BUFFERS 64 EP0BUF EP0-IN/-OUT buffer 64 EP10UTBUF EP1-OUT buffer 64 EP1INBUF EP1-IN buffer 2048 reserved 1023 EP2FIFOBUF 64/1023-byte EP 2 / slave FIFO buffer (IN or OUT) 64 EP4FIFOBUF 64 byte EP 4 / slave FIFO buffer (IN or OUT) 64 reserved 1023 EP6FIFOBUF 64/1023-byte EP 6 / slave FIFO buffer (IN or OUT) D7 D7 D7 D6 D6 D6 D5 D5 D5 D4 D4 D4 D3 D3 D3 D2 D2 D2 D1 D1 D1 D0 D0 D0 xxxxxxxx xxxxxxxx xxxxxxxx D7 D6 D5 D4 D3 D2 D1 D0 xxxxxxxx RW RW RW RW RW D7 D6 D5 D4 D3 D2 D1 D0 xxxxxxxx RW D7 D6 D5 D4 D3 D2 D1 D0 xxxxxxxx RW E6D2 1 E6D3 1 E6D4 1 3 E6DA 1 E6DB 1 E6DC 1 3 E6E2 1 E6E3 1 E6E4 1 3 E6EA 1 E6EB 1 E6EC 1 3 E6F0 1 E6F1 1 E6F2 1 E6F3 1 F000 F400 F600 F800 Document #: 38-08039 Rev. *E 00000000 RW W W W Page 28 of 54 [+] Feedback CY7C64713 Table 9. FX1 Register Summary (continued) Hex Size Name FC00 64 EP8FIFOBUF FE00 64 xxxx Description b7 64 byte EP 8 / slave FIFO D7 buffer (IN or OUT) b6 D6 b5 D5 b4 D4 b3 D3 b2 D2 b1 D1 b0 D0 Default xxxxxxxx Access RW 0 DISCON 0 0 0 0 0 400KHZ xxxxxxxx n/a D7 D7 A7 A15 A7 A15 0 SMOD0 TF1 D6 D6 A6 A14 A6 A14 0 x TR1 D5 D5 A5 A13 A5 A13 0 1 TF0 D4 D4 A4 A12 A4 A12 0 1 TR0 D3 D3 A3 A11 A3 A11 0 x IE1 D2 D2 A2 A10 A2 A10 0 x IT1 D1 D1 A1 A9 A1 A9 0 x IE0 D0 D0 A0 A8 A0 A8 SEL IDLE IT0 xxxxxxxx 00000111 00000000 00000000 00000000 00000000 00000000 00110000 00000000 RW RW RW RW RW RW RW RW RW GATE CT M1 M0 GATE CT M1 M0 00000000 RW D7 D6 D5 D4 D3 D2 D1 D0 00000000 RW D7 D15 D15 x D6 D14 D14 x D5 D13 D13 T2M D4 D12 D12 T1M D3 D11 D11 T0M D2 D10 D10 MD2 D1 D9 D9 MD1 D0 D8 D8 MD0 00000000 00000000 00000000 00000001 Port B (bit addressable) D7 External Interrupt Flag(s) IE5 Upper Addr Byte of MOVX A15 using @R0 / @R1 D6 IE4 A14 D5 I²CINT A13 D4 USBNT A12 D3 1 A11 D2 0 A10 D1 0 A9 D0 0 A8 xxxxxxxx RW 00001000 RW 00000000 RW Serial Port 0 Control (bit addressable) Serial Port 0 Data Buffer Autopointer 1 Address H Autopointer 1 Address L SM0_0 SM1_0 SM2_0 REN_0 TB8_0 RB8_0 TI_0 RI_0 00000000 RW D7 A15 A7 D6 A14 A6 D5 A13 A5 D4 A12 A4 D3 A11 A3 D2 A10 A2 D1 A9 A1 D0 A8 A0 00000000 RW 00000000 RW 00000000 RW Autopointer 2 Address H A15 Autopointer 2 Address L A7 A14 A6 A13 A5 A12 A4 A11 A3 A10 A2 A9 A1 A8 A0 00000000 RW 00000000 RW Port C (bit addressable) Interrupt 2 clear Interrupt 4 clear D7 x x D6 x x D5 x x D4 x x D3 x x D2 x x D1 x x D0 x x xxxxxxxx xxxxxxxx xxxxxxxx Interrupt Enable (bit addressable) EA ES1 ET2 ES0 ET1 EX1 ET0 EX0 00000000 RW EP8E EP6F EP6E EP4F EP4E EP2F EP2E 01011010 R EP4PF EP4EF EP4FF 0 EP2PF EP2EF EP2FF 00100010 R EP8PF EP8EF EP8FF 0 EP6PF EP6EF EP6FF 01100110 R 0 D7 D7 0 D6 D6 0 D5 D5 0 D4 D4 0 D3 D3 APTR2INC D2 D2 APTR1INC D1 D1 APTREN D0 D0 00000110 RW xxxxxxxx RW xxxxxxxx RW D7 D7 D7 D7 D7 D6 D6 D6 D6 D6 D5 D5 D5 D5 D5 D4 D4 D4 D4 D4 D3 D3 D3 D3 D3 D2 D2 D2 D2 D2 D1 D1 D1 D1 D1 D0 D0 D0 D0 D0 00000000 00000000 00000000 00000000 00000000 1 PS1 PT2 PS0 PT1 PX1 PT0 PX0 10000000 RW 0 0 0 0 0 EP1INBSY 00000000 R DONE 0 0 0 0 RW EP1OUTBS EP0BSY Y EP1 EP0 D14 D13 D12 D11 D10 D9 xxxxxxxx reserved I²C Configuration Byte 80 81 82 83 84 85 86 87 88 1 1 1 1 1 1 1 1 1 89 1 8A 1 Special Function Registers (SFRs) IOA[8] Port A (bit addressable) SP Stack Pointer DPL0 Data Pointer 0 L DPH0 Data Pointer 0 H DPL1[8] Data Pointer 1 L DPH1[8] Data Pointer 1 H DPS[8] Data Pointer 0/1 select PCON Power Control TCON Timer/Counter Control (bit addressable) TMOD Timer/Counter Mode Control TL0 Timer 0 reload L 8B 8C 8D 8E 8F 90 91 92 1 1 1 1 1 1 1 1 TL1 TH0 TH1 CKCON[8] reserved IOB[8] EXIF[8] MPAGE[8] 93 98 5 1 reserved SCON0 99 9A 9B 9C 9D 9E 9F A0 A1 A2 A3 A8 1 1 1 1 1 1 1 1 1 1 5 1 SBUF0 AUTOPTRH1[8] AUTOPTRL1[8] reserved AUTOPTRH2[8] AUTOPTRL2[8] reserved IOC[8] INT2CLR[8] INT4CLR[8] reserved IE A9 AA 1 1 reserved EP2468STAT[8] AB 1 EP24FIFOFLGS AC 1 EP68FIFOFLGS AD AF B0 B1 2 1 1 1 B2 B3 B4 B5 B6 B7 B8 1 1 1 1 1 1 1 B9 BA 1 1 reserved AUTOPTRSETUP[8] Autopointer 1&2 setup IOD[8] Port D (bit addressable) IOE[8] Port E (NOT bit addressable) [8] OEA Port A Output Enable OEB[8] Port B Output Enable OEC[8] Port C Output Enable OED[8] Port D Output Enable OEE[8] Port E Output Enable reserved IP Interrupt Priority (bit addressable) reserved EP01STAT[8] Endpoint 0&1 Status BB 1 GPIFTRIG[8] [7] BC BD 1 1 reserved GPIFSGLDATH[8] [8] [8] Timer 1 reload L Timer 0 reload H Timer 1 reload H Clock Control Endpoint 2,4,6,8 status EP8F flags Endpoint 2,4 slave FIFO 0 status flags Endpoint 6,8 slave FIFO 0 status flags Endpoint 2,4,6,8 GPIF slave FIFO Trigger GPIF Data H (16-bit mode D15 only) Document #: 38-08039 Rev. *E D8 [[10]] RW RW RW RW RW W W RW RW RW RW RW 10000xxx brrrrbbb RW Page 29 of 54 [+] Feedback CY7C64713 Table 9. FX1 Register Summary (continued) Hex BE BF C0 Size Name 1 GPIFSGLDATLX[8] 1 GPIFSGLDAT LNOX[8] 1 SCON1[8] C1 C2 C8 1 6 1 SBUF1[8] C9 CA 1 1 reserved RCAP2L CB 1 RCAP2H CC CD CE D0 1 1 2 1 TL2 TH2 reserved PSW D1 D8 D9 E0 7 1 7 1 reserved EICON[8] reserved ACC E1 E8 7 1 reserved EIE[8] E9 F0 F1 F8 7 1 7 1 reserved B reserved EIP[8] F9 7 reserved reserved T2CON Description b7 GPIF Data L w/ Trigger D7 GPIF Data L w/ No Trigger D7 b6 D6 D6 b5 D5 D5 b4 D4 D4 b3 D3 D3 b2 D2 D2 b1 D1 D1 b0 D0 D0 Default xxxxxxxx xxxxxxxx Serial Port 1 Control (bit SM0_1 addressable) Serial Port 1 Data Buffer D7 SM1_1 SM2_1 REN_1 TB8_1 RB8_1 TI_1 RI_1 00000000 RW D6 D5 D4 D3 D2 D1 D0 00000000 RW Timer/Counter 2 Control (bit addressable) TF2 EXF2 RCLK TCLK EXEN2 TR2 CT2 CPRL2 00000000 RW Capture for Timer 2, auto-reload, up-counter Capture for Timer 2, auto-reload, up-counter Timer 2 reload L Timer 2 reload H D7 D6 D5 D4 D3 D2 D1 D0 00000000 RW D7 D6 D5 D4 D3 D2 D1 D0 00000000 RW D7 D15 D6 D14 D5 D13 D4 D12 D3 D11 D2 D10 D1 D9 D0 D8 00000000 RW 00000000 RW Program Status Word (bit CY addressable) AC F0 RS1 RS0 OV F1 P 00000000 RW External Interrupt Control SMOD1 1 ERESI RESI INT6 0 0 0 01000000 RW Accumulator (bit address- D7 able) D6 D5 D4 D3 D2 D1 D0 00000000 RW External Interrupt Enable(s) 1 1 1 EX6 EX5 EX4 EI²C EUSB 11100000 RW B (bit addressable) D7 D6 D5 D4 D3 D2 D1 D0 00000000 RW 1 1 PX6 PX5 PX4 PI²C PUSB 11100000 RW External Interrupt Priority 1 Control Access RW R Legend (For the Access column) R = all bits read-only W = all bits write-only r = read-only bit w = write-only bit b = both read/write bit Note 10. If no EEPROM is detected by the SIE then the default is 00000000. Document #: 38-08039 Rev. *E Page 30 of 54 [+] Feedback CY7C64713 Absolute Maximum Ratings Operating Conditions Exceeding maximum ratings may shorten the useful life of the device. User guidelines are not tested. Supply Voltage............................................+3.15V to +3.45V Storage Temperature .................................. –65°C to +150°C Ground Voltage.................................................................. 0V Ambient Temperature with Power Supplied...... 0°C to +70°C FOSC (Oscillator or Crystal Frequency).... 24 MHz ± 100 ppm Parallel Resonant TA (Ambient Temperature Under Bias) ............. 0°C to +70°C Supply Voltage to Ground Potential................–0.5V to +4.0V DC Input Voltage to Any Input Pin .......................... 5.25V[11] DC Voltage Applied to Outputs in High Z State ..................................... –0.5V to VCC + 0.5V Power Dissipation.................................................... 235 mW Static Discharge Voltage.......................................... > 2000V Max Output Current, per IO port................................. 10 mA Max Output Current, all five IO ports (128 and 100 pin packages) ....................................... 50 mA DC Characteristics Table 10. DC Characteristics Parameter VCC Description Conditions Supply Voltage VCC Ramp Up 0 to 3.3V Min Typ Max Unit 3.15 3.3 3.45 V μs 200 VIH Input HIGH Voltage 2 VIL Input LOW Voltage –0.5 0.8 V VIH_X Crystal input HIGH Voltage 2 5.25 V VIL_X Crystal input LOW Voltage II Input Leakage Current 5.25 –0.05 0< VIN < VCC V 0.8 V ±10 μA 0.4 V VOH Output Voltage HIGH IOUT = 4 mA VOL Output LOW Voltage IOUT = –4 mA IOH Output Current HIGH 4 mA IOL Output Current LOW 4 mA CIN Input Pin Capacitance ISUSP Suspend Current V Except D+/D– 3.29 10 pF D+/D– 12.96 15 pF Connected .5 1.2 mA Disconnected .3 1.0 mA 35 65 mA ICC Supply Current 8051 running, connected to USB TRESET Reset Time after Valid Power VCC min = 3.0V Pin Reset after powered on 2.4 5.0 ms 200 μs USB Transceiver USB 2.0 compliant in full speed mode. Notes 11. It is recommended to not power IO when chip power is off. Document #: 38-08039 Rev. *E Page 31 of 54 [+] Feedback CY7C64713 AC Electrical Characteristics USB Transceiver USB 2.0 compliant in full speed mode. Figure 12. Program Memory Read Timing Diagram tCL CLKOUT[12] tAV tAV A[15..0] tSTBH tSTBL PSEN# [13] tACC1 D[7..0] tDH data in tSOEL OE# tSCSL CS# Table 11. Program Memory Read Parameters Parameter tCL Description Min 1/CLKOUT Frequency Typ Max 20.83 Unit Notes ns 48 MHz 41.66 ns 24 MHz 83.2 ns 12 MHz tAV Delay from Clock to Valid Address 0 10.7 ns tSTBL Clock to PSEN Low 0 8 ns tSTBH Clock to PSEN High 0 tSOEL Clock to OE Low tSCSL Clock to CS Low tDSU Data Setup to Clock tDH Data Hold Time 8 ns 11.1 ns 13 ns 9.6 ns 0 ns Notes 12. CLKOUT is shown with positive polarity. 13. tACC1 is computed from the parameters in Table 11 as follows: tACC1(24 MHz) = 3*tCL – tAV – tDSU = 106 ns tACC1(48 MHz) = 3*tCL – tAV – tDSU = 43 ns. Document #: 38-08039 Rev. *E Page 32 of 54 [+] Feedback CY7C64713 Figure 13. Data Memory Read Timing Diagram tCL Stretch = 0 CLKOUT[12] tAV tAV A[15..0] tSTBH tSTBL RD# tSCSL CS# tSOEL OE# tDSU [14 tDH tACC1 D[7..0] data in tCL Stretch = 1 CLKOUT[12] tAV A[15..0] RD# CS# tDSU tACC1[14] D[7..0] tDH data in Table 12. Data Memory Read Parameters Parameter tCL Description Min 1/CLKOUT Frequency tAV Delay from Clock to Valid Address tSTBL Clock to RD LOW tSTBH tSCSL tSOEL Clock to OE LOW tDSU Data Setup to Clock tDH Data Hold Time Typ Max 20.83 Unit Notes ns 48 MHz 41.66 ns 24 MHz 83.2 ns 12 MHz 10.7 ns 11 ns Clock to RD HIGH 11 ns Clock to CS LOW 13 ns 11.1 ns 9.6 ns 0 ns When using the AUTPOPTR1 or AUTOPTR2 to address external memory, the address of AUTOPTR1 is active only when either RD# or WR# are active. The address of AUTOPTR2 is active throughout the cycle and meets the above address valid time for which is based on the stretch value. Note 14. tACC2 and tACC3 are computed from the parameters in Table 12 as follows: tACC2(24 MHz) = 3*tCL – tAV – tDSU = 106 ns tACC2(48 MHz) = 3*tCL – tAV – tDSU = 43 ns tACC3(24 MHz) = 5*tCL – tAV – tDSU = 190 ns tACC3(48 MHz) = 5*tCL – tAV – tDSU = 86 ns. Document #: 38-08039 Rev. *E Page 33 of 54 [+] Feedback CY7C64713 Figure 14. Data Memory Write Timing Diagram tCL CLKOUT tAV tSTBL tSTBH tAV A[15..0] WR# tSCSL CS# tON1 tOFF1 data out D[7..0] Stretch = 1 tCL CLKOUT tAV A[15..0] WR# CS# tON1 tOFF1 data out D[7..0] Table 13. Data Memory Write Parameters Min Max Unit tAV Parameter Delay from Clock to Valid Address Description 0 10.7 ns tSTBL Clock to WR Pulse LOW 0 11.2 ns tSTBH Clock to WR Pulse HIGH 0 11.2 ns tSCSL Clock to CS Pulse LOW 13.0 ns tON1 Clock to Data Turn-on 0 13.1 ns tOFF1 Clock to Data Hold Time 0 13.1 ns Notes When using the AUTPOPTR1 or AUTOPTR2 to address external memory, the address of AUTOPTR1 is active only when either RD# or WR# are active. The address of AUTOPTR2 is active throughout the cycle and meets the above address valid time for which is based on the stretch value. Document #: 38-08039 Rev. *E Page 34 of 54 [+] Feedback CY7C64713 PORTC Strobe Feature Timings The RD# and WR# are present in the 100 pin version and the 128 pin package. In these 100 pin and 128 pin versions, an 8051 control bit is set to pulse the RD# and WR# pins when the 8051 reads from or writes to the PORTC. This feature is enabled by setting the PORTCSTB bit in CPUCS register. The RD# and WR# strobes are asserted for two CLKOUT cycles when the PORTC is accessed. The WR# strobe is asserted two clock cycles after the PORTC is updated and is active for two clock cycles after that as shown in Figure 16. As for read, the value of the PORTC three clock cycles before the assertion of RD# is the value that the 8051 reads in. The RD# is pulsed for 2 clock cycles after 3 clock cycles from the point when the 8051 has performed a read function on PORTC. In this feature the RD# signal prompts the external logic to prepare the next data byte. Nothing gets sampled internally on assertion of the RD# signal itself. It is just a “prefetch” type signal to get the next data byte prepared. Therfore, using it meets the set up time to the next read. The purpose of this pulsing of RD# is to let the external peripheral know that the 8051 is done reading PORTC and that the data was latched into the PORTC three CLKOUT cycles prior to asserting the RD# signal. After the RD# is pulsed the external logic may update the data on PORTC. The timing diagram of the read and write strobing function on accessing PORTC follows. Refer to Figure 13 on page 33 and Figure 14 on page 34 for details on propagation delay of RD# and WR# signals. Figure 16. WR# Strobe Function when PORTC is Accessed by 8051 tCLKOUT CLKOUT PORTC IS UPDATED tSTBL tSTBH WR# Figure 17. RD# Strobe Function when PORTC is Accessed by 8051 tCLKOUT CLKOUT 8051 READS PORTC DATA IS UPDATED BY EXTERNAL LOGIC DATA MUST BE HELD FOR 3 CLK CYLCES tSTBL tSTBH RD# Document #: 38-08039 Rev. *E Page 35 of 54 [+] Feedback CY7C64713 GPIF Synchronous Signals In the following figure, dashed lines indicate signals with programmable polarity. Figure 18. GPIF Synchronous Signals Timing Diagram tIFCLK IFCLK tSGA GPIFADR[8:0] RDYX tSRY tRYH DATA(input) valid tSGD tDAH CTLX tXCTL DATA(output) N N+1 tXGD The following table provides the GPIF Synchronous Signals Parameters with Internally Sourced IFCLK. [15, 16] Table 14. GPIF Synchronous Signals Parameters with Internally Sourced IFCLK Parameter Description tIFCLK IFCLK Period tSRY RDYX to Clock Setup Time Min Max Unit 20.83 ns 8.9 ns tRYH Clock to RDYX tSGD GPIF Data to Clock Setup Time tDAH GPIF Data Hold Time tSGA Clock to GPIF Address Propagation Delay tXGD Clock to GPIF Data Output Propagation Delay 11 ns tXCTL Clock to CTLX Output Propagation Delay 6.7 ns 0 ns 9.2 ns 0 ns 7.5 ns The following table provides the GPIF Synchronous Signals Parameters with Externally Sourced IFCLK.[16] Table 15. GPIF Synchronous Signals Parameters with Externally Sourced IFCLK Parameter Description Min Max Unit 20.83 200 ns tIFCLK IFCLK Period tSRY RDYX to Clock Setup Time 2.9 ns tRYH Clock to RDYX 3.7 ns tSGD GPIF Data to Clock Setup Time 3.2 ns tDAH GPIF Data Hold Time 4.5 ns tSGA Clock to GPIF Address Propagation Delay tXGD Clock to GPIF Data Output Propagation Delay tXCTL Clock to CTLX Output Propagation Delay 11.5 ns 15 ns 10.7 ns Notes 15. GPIF asynchronous RDYx signals have a minimum Setup time of 50 ns when using internal 48-MHz IFCLK. 16. IFCLK must not exceed 48 MHz. Document #: 38-08039 Rev. *E Page 36 of 54 [+] Feedback CY7C64713 Slave FIFO Synchronous Read In the following figure, dashed lines indicate signals with programmable polarity. Figure 19. Slave FIFO Synchronous Read Timing Diagram tIFCLK IFCLK tSRD tRDH SLRD tXFLG FLAGS DATA N tOEon N+1 tXFD tOEoff SLOE The following table provides the Slave FIFO Synchronous Read Parameters with Internally Sourced IFCLK. [16] Table 16. Slave FIFO Synchronous Read Parameters with Internally Sourced IFCLK Parameter Description Min Max Unit tIFCLK IFCLK Period 20.83 ns tSRD SLRD to Clock Setup Time 18.7 ns tRDH Clock to SLRD Hold Time 0 ns tOEon SLOE Turn on to FIFO Data Valid 10.5 ns tOEoff SLOE Turn off to FIFO Data Hold 10.5 ns tXFLG Clock to FLAGS Output Propagation Delay 9.5 ns tXFD Clock to FIFO Data Output Propagation Delay 11 ns The following table provides the Slave FIFO Synchronous Read Parameters with Externally Sourced IFCLK.[16] Table 17. Slave FIFO Synchronous Read Parameters with Externally Sourced IFCLK Min Max Unit tIFCLK Parameter IFCLK Period Description 20.83 200 ns tSRD SLRD to Clock Setup Time 12.7 ns tRDH Clock to SLRD Hold Time 3.7 ns tOEon SLOE Turn on to FIFO Data Valid 10.5 ns tOEoff SLOE Turn off to FIFO Data Hold 10.5 ns tXFLG Clock to FLAGS Output Propagation Delay 13.5 ns tXFD Clock to FIFO Data Output Propagation Delay 15 ns Document #: 38-08039 Rev. *E Page 37 of 54 [+] Feedback CY7C64713 Slave FIFO Asynchronous Read In the following figure, dashed lines indicate signals with programmable polarity. Figure 20. Slave FIFO Asynchronous Read Timing Diagram tRDpwh SLRD tRDpwl tXFLG tXFD FLAGS DATA N N+1 tOEon tOEoff SLOE In the following table, the Slave FIFO asynchronous parameter values use internal IFCLK setting at 48 MHz. Table 18. Slave FIFO Asynchronous Read Parameters Parameter Description Min Max Unit tRDpwl SLRD Pulse Width LOW 50 tRDpwh SLRD Pulse Width HIGH 50 tXFLG SLRD to FLAGS Output Propagation Delay tXFD SLRD to FIFO Data Output Propagation Delay tOEon SLOE Turn-on to FIFO Data Valid tOEoff SLOE Turn-off to FIFO Data Hold 10.5 ns Document #: 38-08039 Rev. *E ns ns 70 ns 15 ns 10.5 ns Page 38 of 54 [+] Feedback CY7C64713 Slave FIFO Synchronous Write In the following figure, dashed lines indicate signals with programmable polarity. Figure 21. Slave FIFO Synchronous Write Timing Diagram tIFCLK IFCLK SLWR DATA tSWR tWRH N Z tSFD Z tFDH FLAGS tXFLG The following table provides the Slave FIFO Synchronous Write Parameters with Internally Sourced IFCLK. [16] Table 19. Slave FIFO Synchronous Write Parameters with Internally Sourced IFCLK Parameter Description Min Max Unit tIFCLK IFCLK Period 20.83 tSWR SLWR to Clock Setup Time 18.1 ns tWRH Clock to SLWR Hold Time 0 ns tSFD FIFO Data to Clock Setup Time 9.2 ns tFDH Clock to FIFO Data Hold Time 0 ns tXFLG Clock to FLAGS Output Propagation Time ns 9.5 ns The following table provides the Slave FIFO Synchronous Write Parameters with Externally Sourced IFCLK. [16] Table 20. Slave FIFO Synchronous Write Parameters with Externally Sourced IFCLK [16] Min Max Unit tIFCLK Parameter IFCLK Period Description 20.83 200 ns tSWR SLWR to Clock Setup Time 12.1 ns tWRH Clock to SLWR Hold Time 3.6 ns tSFD FIFO Data to Clock Setup Time 3.2 ns tFDH Clock to FIFO Data Hold Time 4.5 ns tXFLG Clock to FLAGS Output Propagation Time Document #: 38-08039 Rev. *E 13.5 ns Page 39 of 54 [+] Feedback CY7C64713 Slave FIFO Asynchronous Write In the following figure, dashed lines indicate signals with programmable polarity. Figure 22. Slave FIFO Asynchronous Write Timing Diagram tWRpwh SLWR/SLCS# tWRpwl tSFD tFDH DATA tXFD FLAGS In the following table, the Slave FIFO asynchronous parameter values use internal IFCLK setting at 48 MHz. Table 21. Slave FIFO Asynchronous Write Parameters with Internally Sourced IFCLK Parameter Description Min Max Unit tWRpwl SLWR Pulse LOW 50 ns tWRpwh SLWR Pulse HIGH 70 ns tSFD SLWR to FIFO DATA Setup Time 10 ns tFDH FIFO DATA to SLWR Hold Time 10 ns tXFD SLWR to FLAGS Output Propagation Delay 70 ns Slave FIFO Synchronous Packet End Strobe In the following figure, dashed lines indicate signals with programmable polarity. Figure 23. Slave FIFO Synchronous Packet End Strobe Timing Diagram IFCLK tPEH PKTEND tSPE FLAGS tXFLG The following table provides the Slave FIFO Synchronous Packet End Strobe Parameters with Internally Sourced IFCLK. [16] Table 22. Slave FIFO Synchronous Packet End Strobe Parameters with Internally Sourced IFCLK Parameter Description Min Max Unit tIFCLK IFCLK Period 20.83 ns tSPE PKTEND to Clock Setup Time 14.6 ns tPEH Clock to PKTEND Hold Time 0 tXFLG Clock to FLAGS Output Propagation Delay Document #: 38-08039 Rev. *E ns 9.5 ns Page 40 of 54 [+] Feedback CY7C64713 The following table provides the Slave FIFO Synchronous Packet End Strobe Parameters with Externally Sourced IFCLK. [16] Table 23. Slave FIFO Synchronous Packet End Strobe Parameters with Externally Sourced IFCLK Parameter Description Min Max 20.83 200 tIFCLK IFCLK Period tSPE PKTEND to Clock Setup Time 8.6 tPEH Clock to PKTEND Hold Time 2.5 tXFLG Clock to FLAGS Output Propagation Delay There is no specific timing requirement that needs to be met for asserting the PKTEND pin concerning asserting SLWR. PKTEND is asserted with the last data value clocked into the FIFOs or thereafter. The only consideration is that the set up time tSPE and the hold time tPEH for PKTEND must be met. Although there are no specific timing requirements for asserting PKTEND in relation to SLWR, there exists a specific case condition that needs attention. When using the PKTEND to commit a one byte or word packet, an additional timing requirement must be met when the FIFO is configured to operate in auto mode and it is necessary to send two packets back to back: ■ A full packet (defined as the number of bytes in the FIFO meeting the level set in the AUTOINLEN register) committed automatically followed by ■ A short one byte or word packet committed manually using the PKTEND pin. Unit ns ns ns 13.5 ns In this particular scenario, the developer must assert the PKTEND at least one clock cycle after the rising edge that caused the last byte or word to be clocked into the previous auto committed packet. Figure 24 shows this scenario. X is the value the AUTOINLEN register is set to when the IN endpoint is configured to be in auto mode. Figure 24 shows a scenario where two packets are being committed. The first packet is committed automatically when the number of bytes in the FIFO reaches X (value set in AUTOINLEN register) and the second one byte or word short packet being committed manually using PKTEND. Note that there is at least one IFCLK cycle timing between asserting PKTEND and clocking of the last byte of the previous packet (causing the packet to be committed automatically). Failing to adhere to this timing results in the FX2 failing to send the one byte or word short packet. Figure 24. Slave FIFO Synchronous Write Sequence and Timing Diagram tIFCLK IFCLK tSFA tFAH FIFOADR >= tWRH >= tSWR SLWR tSFD DATA X-4 tFDH tSFD X-3 tFDH tSFD X-2 tFDH tSFD X-1 tFDH tSFD X tFDH tSFD tFDH 1 At least one IFCLK cycle tSPE tPEH PKTEND Document #: 38-08039 Rev. *E Page 41 of 54 [+] Feedback CY7C64713 Slave FIFO Asynchronous Packet End Strobe In the following figure, dashed lines indicate signals with programmable polarity. Figure 25. Slave FIFO Asynchronous Packet End Strobe Timing Diagram tPEpwh PKTEND tPEpwl FLAGS tXFLG In the following table, the Slave FIFO asynchronous parameter values use internal IFCLK setting at 48 MHz. Table 24. Slave FIFO Asynchronous Packet End Strobe Parameters Parameter Description Min tPEpwl PKTEND Pulse Width LOW 50 tPWpwh PKTEND Pulse Width HIGH 50 tXFLG PKTEND to FLAGS Output Propagation Delay Max Unit ns ns 115 ns Slave FIFO Output Enable In the following figure, dashed lines indicate signals with programmable polarity. Figure 26. Slave FIFO Output Enable Timing Diagram SLOE tOEoff tOEon DATA Table 25. Slave FIFO Output Enable Parameters Parameter Description Max Unit tOEon SLOE Assert to FIFO DATA Output 10.5 ns tOEoff SLOE Deassert to FIFO DATA Hold 10.5 ns Slave FIFO Address to Flags/Data In the following figure, dashed lines indicate signals with programmable polarity. Figure 27. Slave FIFO Address to Flags/Data Timing Diagram FIFOADR [1.0] tXFLG FLAGS tXFD DATA N N+1 Table 26. Slave FIFO Address to Flags/Data Parameters Parameter Description Max Unit tXFLG FIFOADR[1:0] to FLAGS Output Propagation Delay 10.7 ns tXFD FIFOADR[1:0] to FIFODATA Output Propagation Delay 14.3 ns Document #: 38-08039 Rev. *E Page 42 of 54 [+] Feedback CY7C64713 Slave FIFO Synchronous Address Figure 28. Slave FIFO Synchronous Address Timing Diagram IFCLK SLCS/FIFOADR [1:0] tSFA tFAH The following table provides the Slave FIFO Synchronous Address Parameters.[16] Table 27. Slave FIFO Synchronous Address Parameters Parameter Description Min Max Unit 20.83 200 ns tIFCLK Interface Clock Period tSFA FIFOADR[1:0] to Clock Setup Time 25 ns tFAH Clock to FIFOADR[1:0] Hold Time 10 ns Slave FIFO Asynchronous Address In the following figure, dashed lines indicate signals with programmable polarity. Figure 29. Slave FIFO Asynchronous Address Timing Diagram SLCS/FIFOADR [1:0] tSFA tFAH RD/WR/PKTEND In the following table, the Slave FIFO asynchronous parameter values use internal IFCLK setting at 48 MHz. Table 28. Slave FIFO Asynchronous Address Parameters Parameter Description Min Unit tSFA FIFOADR[1:0] to RD/WR/PKTEND Setup Time 10 ns tFAH RD/WR/PKTEND to FIFOADR[1:0] Hold Time 10 ns Document #: 38-08039 Rev. *E Page 43 of 54 [+] Feedback CY7C64713 Sequence Diagram Single and Burst Synchronous Read Example Figure 30. Slave FIFO Synchronous Read Sequence and Timing Diagram tIFCLK IFCLK tSFA tSFA tFAH tFAH FIFOADR t=0 tSRD T=0 tRDH >= tSRD >= tRDH SLRD t=3 t=2 T=3 T=2 SLCS tXFLG FLAGS tXFD tXFD Data Driven: N DATA N+1 N+2 N+1 N+3 tOEon tOEoff tOEon tXFD tXFD N+4 tOEoff SLOE t=4 t=1 T=4 T=1 Figure 31. Slave FIFO Synchronous Sequence of Events Diagram IFCLK FIFO POINTER N IFCLK IFCLK N N+1 FIFO DATA BUS Not Driven Driven: N N+1 N+1 Not Driven ■ At t = 1, SLOE is asserted. SLOE is an output enable only, whose sole function is to drive the data bus. The data that is driven on the bus is the data that the internal FIFO pointer is currently pointing to. In this example it is the first data value in the FIFO. Note The data is pre-fetched and is driven on the bus when SLOE is asserted. Document #: 38-08039 Rev. *E IFCLK N+3 IFCLK N+4 N+1 IFCLK N+4 SLRD N+2 N+3 N+4 IFCLK N+4 SLOE N+4 Not Driven ■ At t = 2, SLRD is asserted. SLRD must meet the setup time of tSRD (time from asserting the SLRD signal to the rising edge of the IFCLK) and maintain a minimum hold time of tRDH (time from the IFCLK edge to the deassertion of the SLRD signal). If the SLCS signal is used, it must be asserted with SLRD, or before SLRD is asserted (that is, the SLCS and SLRD signals must both be asserted to start a valid read condition). ■ The FIFO pointer is updated on the rising edge of the IFCLK, while SLRD is asserted. This starts the propagation of data from the newly addressed location to the data bus. After a propagation delay of tXFD (measured from the rising edge of IFCLK) the new data value is present. N is the first data value read from the FIFO. To have data on the FIFO data bus, SLOE MUST also be asserted. At t = 0 the FIFO address is stable and the signal SLCS is asserted (SLCS may be tied low in some applications). Note tSFA has a minimum of 25 ns. This means when IFCLK is running at 48 MHz, the FIFO address setup time is more than one IFCLK cycle. IFCLK N+2 SLRD SLOE Figure 30 shows the timing relationship of the SLAVE FIFO signals during a synchronous FIFO read using IFCLK as the synchronizing clock. This diagram illustrates a single read followed by a burst read. ■ N+1 SLOE SLRD SLRD SLOE IFCLK IFCLK The same sequence of events are shown for a burst read and are marked with the time indicators of T = 0 through 5. Page 44 of 54 [+] Feedback CY7C64713 Note For the burst mode, the SLRD and SLOE are left asserted during the entire duration of the read. In the burst read mode, when SLOE is asserted, data indexed by the FIFO pointer is on the data bus. During the first read cycle, on the rising edge of the clock the FIFO pointer is updated and increments to point to address N+1. For each subsequent rising edge of IFCLK, while the SLRD is asserted, the FIFO pointer is incremented and the next data value is placed on the data bus. Single and Burst Synchronous Write In the following figure, dashed lines indicate signals with programmable polarity. Figure 32. Slave FIFO Synchronous Write Sequence and Timing Diagram tIFCLK IFCLK tSFA tSFA tFAH tFAH FIFOADR t=0 tSWR tWRH >= tWRH >= tSWR T=0 SLWR t=2 T=2 t=3 T=5 SLCS tXFLG tXFLG FLAGS tFDH tSFD tSFD N+1 N DATA t=1 tFDH T=1 tSFD tSFD tFDH N+3 N+2 T=3 tFDH T=4 tSPE tPEH PKTEND Figure 32 shows the timing relationship of the SLAVE FIFO signals during a synchronous write using IFCLK as the synchronizing clock. This diagram illustrates a single write followed by burst write of 3 bytes and committing all 4 bytes as a short packet using the PKTEND pin. ■ At t = 0 the FIFO address is stable and the signal SLCS is asserted (SLCS may be tied low in some applications). Note tSFA has a minimum of 25 ns. This means when IFCLK is running at 48 MHz, the FIFO address setup time is more than one IFCLK cycle. ■ At t = 1, the external master or peripheral must output the data value onto the data bus with a minimum set up time of tSFD before the rising edge of IFCLK. ■ At t = 2, SLWR is asserted. The SLWR must meet the setup time of tSWR (time from asserting the SLWR signal to the rising edge of IFCLK) and maintain a minimum hold time of tWRH (time from the IFCLK edge to the deassertion of the SLWR signal). If SLCS signal is used, it must be asserted with SLWR or before SLWR is asserted. (that is the SLCS and SLWR signals must both be asserted to start a valid write condition). ■ While the SLWR is asserted, data is written to the FIFO and on the rising edge of the IFCLK, the FIFO pointer is incremented. Document #: 38-08039 Rev. *E The FIFO flag is also updated after a delay of tXFLG from the rising edge of the clock. The same sequence of events are also shown for a burst write and are marked with the time indicators of T = 0 through 5. Note For the burst mode, SLWR and SLCS are left asserted for the entire duration of writing all the required data values. In this burst write mode, after the SLWR is asserted, the data on the FIFO data bus is written to the FIFO on every rising edge of IFCLK. The FIFO pointer is updated on each rising edge of IFCLK. In Figure 32, after the four bytes are written to the FIFO, SLWR is deasserted. The short 4-byte packet is committed to the host by asserting the PKTEND signal. There is no specific timing requirement that must be met for asserting the PKTEND signal with regards to asserting the SLWR signal. PKTEND is asserted with the last data value or thereafter. The only consideration is the setup time tSPE and the hold time tPEH must be met. In the scenario of Figure 32, the number of data values committed includes the last value written to the FIFO. In this example, both the data value and the PKTEND signal are clocked on the same rising edge of IFCLK. PKTEND is asserted in subsequent clock cycles. The FIFOADDR lines must be held constant during the PKTEND assertion. Page 45 of 54 [+] Feedback CY7C64713 packet committed manually using the PKTEND pin. In this case, the external master must make sure to assert the PKTEND pin at least one clock cycle after the rising edge that caused the last byte or word to be clocked into the previous auto committed packet (the packet with the number of bytes equal to what is set in the AUTOINLEN register). Refer to Table 20 on page 39 for further details on this timing. Although there are no specific timing requirement for asserting PKTEND, there is a specific corner case condition that needs attention while using the PKTEND to commit a one byte or word packet. Additional timing requirements exist when the FIFO is configured to operate in auto mode and it is necessary to send two packets: a full packet (full defined as the number of bytes in the FIFO meeting the level set in AUTOINLEN register) committed automatically followed by a short one byte or word Sequence Diagram of a Single and Burst Asynchronous Read Figure 33. Slave FIFO Asynchronous Read Sequence and Timing Diagram tSFA tFAH tSFA tFAH FIFOADR t=0 tRDpwl tRDpwh tRDpwl T=0 tRDpwl tRDpwh tRDpwl tRDpwh tRDpwh SLRD t=2 t=3 T=3 T=2 T=5 T=4 T=6 SLCS tXFLG tXFLG FLAGS tXFD Data (X) Driven DATA tXFD tXFD N N N+3 N+2 tOEon tOEoff tOEon tXFD N+1 tOEoff SLOE t=4 t=1 T=7 T=1 Figure 34. Slave FIFO Asynchronous Read Sequence of Events Diagram SLOE FIFO POINTER N FIFO DATA BUS Not Driven SLRD SLRD SLOE SLOE SLRD SLRD SLRD SLRD SLOE N N N+1 N+1 N+1 N+1 N+2 N+2 N+3 N+3 Driven: X N N Not Driven N N+1 N+1 N+2 N+2 Not Driven Figure 33 shows the timing relationship of the SLAVE FIFO signals during an asynchronous FIFO read. It shows a single read followed by a burst read. ■ The data that drives after asserting SLRD, is the updated data from the FIFO. This data is valid after a propagation delay of tXFD from the activating edge of SLRD. In Figure 33, data N is the first valid data read from the FIFO. For data to appear on the data bus during the read cycle (that is, SLRD is asserted), SLOE MUST be in an asserted state. SLRD and SLOE can also be tied together. ■ At t = 0 the FIFO address is stable and the SLCS signal is asserted. ■ At t = 1, SLOE is asserted. This results in the data bus being driven. The data that is driven on to the bus is previous data, it data that was in the FIFO from a prior read cycle. The same sequence of events is also shown for a burst read marked with T = 0 through 5. At t = 2, SLRD is asserted. The SLRD must meet the minimum active pulse of tRDpwl and minimum de-active pulse width of tRDpwh. If SLCS is used then, SLCS must be in asserted with SLRD or before SLRD is asserted (that is, the SLCS and SLRD signals must both be asserted to start a valid read condition). Note In burst read mode, during SLOE is assertion, the data bus is in a driven state and outputs the previous data. After the SLRD is asserted, the data from the FIFO is driven on the data bus (SLOE must also be asserted) and then the FIFO pointer is incremented. ■ Document #: 38-08039 Rev. *E Page 46 of 54 [+] Feedback CY7C64713 Sequence Diagram of a Single and Burst Asynchronous Write In the following figure, dashed lines indicate signals with programmable polarity. Figure 35. Slave FIFO Asynchronous Write Sequence and Timing Diagram tSFA tFAH tSFA tFAH FIFOADR t=0 tWRpwl tWRpwh T=0 tWRpwl tWRpwl tWRpwh tWRpwl tWRpwh tWRpwh SLWR t=3 t =1 T=1 T=3 T=4 T=6 T=7 T=9 SLCS tXFLG tXFLG FLAGS tSFD tFDH tSFD tFDH tSFD tFDH tSFD tFDH N+1 N+2 N+3 N DATA t=2 T=2 T=5 T=8 tPEpwl tPEpwh PKTEND Figure 35 shows the timing relationship of the SLAVE FIFO write in an asynchronous mode. This diagram shows a single write followed by a burst write of 3 bytes and committing the 4-byte-short packet using PKTEND. ■ At t = 0 the FIFO address is applied, insuring that it meets the setup time of tSFA. If SLCS is used, it must also be asserted (SLCS may be tied low in some applications). ■ At t = 1 SLWR is asserted. SLWR must meet the minimum active pulse of tWRpwl and minimum de-active pulse width of tWRpwh. If the SLCS is used, it must be in asserted with SLWR or before SLWR is asserted. ■ At t = 2, data must be present on the bus tSFD before the deasserting edge of SLWR. ■ At t = 3, deasserting SLWR causes the data to be written from the data bus to the FIFO and then increments the FIFO pointer. Document #: 38-08039 Rev. *E The FIFO flag is also updated after tXFLG from the deasserting edge of SLWR. The same sequence of events are shown for a burst write and is indicated by the timing marks of T = 0 through 5. Note In the burst write mode, after SLWR is deasserted, the data is written to the FIFO and then the FIFO pointer is incremented to the next byte in the FIFO. The FIFO pointer is post incremented. In Figure 35, after the four bytes are written to the FIFO and SLWR is deasserted, the short 4-byte packet is committed to the host using the PKTEND. The external device must be designed to not assert SLWR and the PKTEND signal at the same time. It must be designed to assert the PKTEND after SLWR is deasserted and has met the minimum deasserted pulse width. The FIFOADDR lines are to be held constant during the PKTEND assertion. Page 47 of 54 [+] Feedback CY7C64713 Ordering Information Table 29. Ordering Information Ordering Code Package Type RAM Size # Prog IOs 8051 Address /Data Busses CY7C64713-128AXC 128 TQFP - Pb-free 16K 40 16/8 bit CY7C64713-100AXC 100 TQFP - Pb-free 16K 40 - CY7C64713-56PVXC 56 SSOP - Pb-free 16K 24 - CY7C64713-56LFXC 56 QFN - Pb-free 16K 24 - CY3674 EZ-USB FX1 Development Kit Document #: 38-08039 Rev. *E Page 48 of 54 [+] Feedback CY7C64713 Package Diagrams The FX1 is available in four packages: ■ 56 Pin SSOP ■ 56 Pin QFN ■ 100 Pin TQFP ■ 128 Pin TQFP Figure 36. 56 Pin Shrunk Small Outline Package O56 51-85062-*C Document #: 38-08039 Rev. *E Page 49 of 54 [+] Feedback CY7C64713 Figure 37. 56 Pin QFN 8 x 8 mm LF56A SIDE VIEW TOP VIEW BOTTOM VIEW 0.08[0.003] 7.90[0.311] 8.10[0.319] A C 1.00[0.039] MAX. 6.1 0.05[0.002] MAX. 0.18[0.007] 0.28[0.011] 0.80[0.031] MAX. 0.20[0.008] REF. N 1 2 2 7.90[0.311] 8.10[0.319] 1 7.70[0.303] 7.80[0.307] 0.80[0.031] DIA. PIN1 ID 0.20[0.008] R. N 6.1 0°-12° C SEATING PLANE 0.45[0.018] SOLDERABLE EXPOSED PAD 0.30[0.012] 0.50[0.020] 0.50[0.020] 6.45[0.254] 6.55[0.258] 7.70[0.303] 7.80[0.307] 0.24[0.009] 0.60[0.024] (4X) 6.45[0.254] 6.55[0.258] NOTES: 1. HATCH AREA IS SOLDERABLE EXPOSED METAL. 2. REFERENCE JEDEC#: MO-220 3. PACKAGE WEIGHT: 0.162g 4. ALL DIMENSIONS ARE IN MM [MIN/MAX] 5. PACKAGE CODE PART # DESCRIPTION LF56 LY56 STANDARD PB-FREE Document #: 38-08039 Rev. *E 51-85144-*G (SUBCON PUNCH TYPE PKG with 6.1 x 6.1 EPAD) Page 50 of 54 [+] Feedback CY7C64713 Figure 38. 100 Pin Thin Plastic Quad Flatpack (14 x 20 x 1.4 mm) A101 16.00±0.20 1.40±0.05 14.00±0.10 100 81 80 1 20.00±0.10 22.00±0.20 0.30±0.08 0.65 TYP. 30 12°±1° (8X) SEE DETAIL A 51 31 50 0.20 MAX. 0.10 1.60 MAX. R 0.08 MIN. 0.20 MAX. 0° MIN. SEATING PLANE STAND-OFF 0.05 MIN. 0.15 MAX. 0.25 NOTE: 1. JEDEC STD REF MS-026 GAUGE PLANE 0°-7° R 0.08 MIN. 0.20 MAX. 2. BODY LENGTH DIMENSION DOES NOT INCLUDE MOLD PROTRUSION/END FLASH MOLD PROTRUSION/END FLASH SHALL NOT EXCEED 0.0098 in (0.25 mm) PER SIDE BODY LENGTH DIMENSIONS ARE MAX PLASTIC BODY SIZE INCLUDING MOLD MISMATCH 3. DIMENSIONS IN MILLIMETERS 0.60±0.15 0.20 MIN. 1.00 REF. DETAIL Document #: 38-08039 Rev. *E A 51-85050-*B Page 51 of 54 [+] Feedback CY7C64713 Figure 39. 128 Pin Thin Plastic Quad Flatpack (14 x 20 x 1.4 mm) A128 16.00±0.20 14.00±0.10 1.40±0.05 128 1 20.00±0.10 22.00±0.20 0.22±0.05 12°±1° (8X) 0.50 TYP. SEE DETAIL A 0.20 MAX. 1.60 MAX. 0° MIN. 0.08 R 0.08 MIN. 0.20 MAX. STAND-OFF 0.05 MIN. 0.15 MAX. 0.25 GAUGE PLANE 0°-7° R 0.08 MIN. 0.20 MAX. SEATING PLANE NOTE: 1. JEDEC STD REF MS-026 2. BODY LENGTH DIMENSION DOES NOT INCLUDE MOLD PROTRUSION/END FLASH MOLD PROTRUSION/END FLASH SHALL NOT EXCEED 0.0098 in (0.25 mm) PER SIDE BODY LENGTH DIMENSIONS ARE MAX PLASTIC BODY SIZE INCLUDING MOLD MISMATCH 3. DIMENSIONS IN MILLIMETERS 0.60±0.15 0.20 MIN. 1.00 REF. DETAIL A Quad Flat Package No Leads (QFN) Package Design Notes Electrical contact of the part to the Printed Circuit Board (PCB) is made by soldering the leads on the bottom surface of the package to the PCB. Aas a result, special attention is required to the heat transfer area below the package to provide a good thermal bond to the circuit board. A Copper (Cu) fill is to be designed into the PCB as a thermal pad under the package. Heat is transferred from the FX1 through the device’s metal paddle on the bottom side of the package. Heat from here, is conducted to the PCB at the thermal pad. It is then conducted from the thermal pad to the PCB inner ground plane by a 5 x 5 array of via. A via is a plated through hole in the PCB with a finished diameter of 13 mil. The QFN’s metal die paddle must be soldered to the PCB’s thermal pad. Solder mask is placed on the board top side over each via to resist solder flow into the via. The mask on the top side also minimizes outgassing during the solder reflow process. Document #: 38-08039 Rev. *E 51-85101 *C For further information on this package design please refer to ‘Application Notes for Surface Mount Assembly of Amkor's MicroLeadFrame (MLF) Packages’. This can be found on Amkor's website http://www.amkor.com. The application note provides detailed information on board mounting guidelines, soldering flow, rework process, and so on. Figure 40 displays a cross-sectional area underneath the package. The cross section is of only one via. The solder paste template needs to be designed to allow at least 50% solder coverage. The thickness of the solder paste template must be 5 mil. It is recommended that ‘No Clean’ type 3 solder paste is used for mounting the part. Nitrogen purge is recommended during reflow. Figure 41 is a plot of the solder mask pattern and Figure 42 displays an X-Ray image of the assembly (darker areas indicate solder). Page 52 of 54 [+] Feedback CY7C64713 Figure 40. Cross section of the Area Underneath the QFN Package 0.017” dia Solder Mask Cu Fill Cu Fill PCB Material Via hole for thermally connecting the QFN to the circuit board ground plane. 0.013” dia PCB Material This figure only shows the top three layers of the circuit board: Top Solder, PCB Dielectric, and the Ground Plane. Figure 41. Plot of the Solder Mask (White Area) Figure 42. X-ray Image of the Assembly Document #: 38-08039 Rev. *E Page 53 of 54 [+] Feedback CY7C64713 Document History Page Document Title: CY7C64713 EZ-USB FX1™ USB Microcontroller Full-Speed USB Peripheral Controller Document Number: 38-08039 REV. ECN NO. Issue Date Orig. of Change ** 132091 02/10/04 KKU New Data Sheet. *A 230709 SEE ECN KKU Changed Lead free Marketing part numbers in Table 29 according to spec change in 28-00054. *B 307474 SEE ECN BHA Changed default PID in Table 2 on page 4. Updated register table. Removed word compatible where associated with I2C. Changed Set-up to Setup. Added Power Dissipation. Changed Vcc from ± 10% to ± 5% Added values for VIH_X, VIL_X Added values for ICC Added values for ISUSP Removed IUNCONFIGURED from Table 10 on page 31. Changed PKTEND to FLAGS output propagation delay (asynchronous interface) in Table 10-14 from a maximum value of 70 ns to 115 ns. Removed 56 SSOP and added 56 QFN package. Provided additional timing restrictions and requirement regarding the use of PKTEND pin to commit a short one byte/word packet subsequent to committing a packet automatically (when in auto mode). Added part number CY7C64714 ideal for battery powered applications. Changed Supply Voltage in section 8 to read +3.15V to +3.45V. Added Min Vcc Ramp Up time (0 to 3.3v). Removed Preliminary. *C 392702 SEE ECN BHA Corrected signal name for pin 54 in Figure 10 on page 15. Added information on the AUTOPTR1/AUTOPTR2 address timing with regards to data memory read/write timing diagram. Removed TBD in Table 16 on page 37. Added section “PORTC Strobe Feature Timings” on page 35. *D 1664787 See ECN CMCC/ JASM *E 2088446 See ECN JASM Description of Change Added the 56 pin SSOP pinout and package information. Delete CY7C64714 Updated package diagrams © Cypress Semiconductor Corporation, 2004-2008. The information contained herein is subject to change without notice. Cypress Semiconductor Corporation assumes no responsibility for the use of any circuitry other than circuitry embodied in a Cypress product. Nor does it convey or imply any license under patent or other rights. Cypress products are not warranted nor intended to be used for medical, life support, life saving, critical control or safety applications, unless pursuant to an express written agreement with Cypress. Furthermore, Cypress does not authorize its products for use as critical components in life-support systems where a malfunction or failure may reasonably be expected to result in significant injury to the user. The inclusion of Cypress products in life-support systems application implies that the manufacturer assumes all risk of such use and in doing so indemnifies Cypress against all charges. Any Source Code (software and/or firmware) is owned by Cypress Semiconductor Corporation (Cypress) and is protected by and subject to worldwide patent protection (United States and foreign), United States copyright laws and international treaty provisions. Cypress hereby grants to licensee a personal, non-exclusive, non-transferable license to copy, use, modify, create derivative works of, and compile the Cypress Source Code and derivative works for the sole purpose of creating custom software and or firmware in support of licensee product to be used only in conjunction with a Cypress integrated circuit as specified in the applicable agreement. Any reproduction, modification, translation, compilation, or representation of this Source Code except as specified above is prohibited without the express written permission of Cypress. Disclaimer: CYPRESS MAKES NO WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, WITH REGARD TO THIS MATERIAL, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE. Cypress reserves the right to make changes without further notice to the materials described herein. Cypress does not assume any liability arising out of the application or use of any product or circuit described herein. Cypress does not authorize its products for use as critical components in life-support systems where a malfunction or failure may reasonably be expected to result in significant injury to the user. The inclusion of Cypress’ product in a life-support systems application implies that the manufacturer assumes all risk of such use and in doing so indemnifies Cypress against all charges. Use may be limited by and subject to the applicable Cypress software license agreement. Document #: 38-08039 Rev. *E Revised February 06, 2008 Page 54 of 54 Purchase of I2C components from Cypress, or one of its sublicensed Associated Companies, conveys a license under the Philips I2C Patent Rights to use these components in an I2C system, provided that the system conforms to the I2C Standard Specification as defined by Philips. EZ-USB FX1, EZ-USB FX2LP, EZ-USB FX2, and ReNumeration are trademarks, and EZ-USB is a registered trademark, of Cypress Semiconductor. All product and company names mentioned in this document are the trademarks of their respective holders. [+] Feedback